JP5291841B1 - Wave damping block - Google Patents

Abstract

【Task】
It not only attenuates the energy of the waves and prevents them from getting over, but it also persists in structures such as breakwaters.
[Solution]
The wave force attenuation block 10 is formed in a substantially rectangular parallelepiped shape having a front surface 11, an upper surface 12, a rear surface 13, a lower surface 14, a right surface 15 and a left surface 16. In addition, the vertical width direction intermediate portion 11a on the front surface 11, the front / rear width direction intermediate portion 12a on the upper surface 12, the vertical width direction intermediate portion 13a on the rear surface 13 and the front / rear width direction intermediate portion 14a on the lower surface 14 are respectively recessed. By forming a cylindrical surface, the corner between the front surface 11 and the upper surface 12, the corner between the upper surface 12 and the rear surface 13, the corner between the rear surface 13 and the lower surface 14, and the corner between the lower surface 14 and the front surface 11, A first overhang 17a, a second overhang 17b, a third overhang 17c, and a fourth overhang 17d were formed.
[Selection] Figure 1

Description

  The present invention relates to a wave force attenuation block that can be used for revetment or for constructing structures such as breakwaters and seawalls.

  Conventionally, revetment has been carried out by constructing wave-dissipating blocks on the coast or riverbank. Wave-dissipating blocks are often built in multiple rows and multiple stages on the sea side of existing breakwaters. As a wave-dissipating block, one having an approximately regular tetrahedron shape in which four leg portions project radially from the center (hereinafter referred to as “regular tetrahedral wave-dissipating block”) is widely known. (For example, see Patent Document 1). The regular tetrahedral wave extinguishing block can attenuate or dissipate the energy of waves that reach the coast and the like, and has a certain effect for preventing erosion of the coast and the like. However, since the gaps are formed between the wave-dissipating blocks when stacked, the effect is limited. In addition, when the wave is strong, the wave hitting the wave-dissipating block may get over the wave-dissipating block and the breakwater behind it to reach the land.

  In the meantime, various forms of wave-dissipating blocks have been proposed in addition to tetrahedral wave-dissipating blocks. For example, a wave-dissipating block (hereinafter referred to as “cross-sectional Y-shaped wave-dissipating block”) in which a cross section perpendicular to the longitudinal direction forms a Y-shaped columnar body has been proposed (for example, Patent Document 2). (See FIG. 1, FIG. 2 of Patent Document 3, and FIG. 1 (I) of Patent Document 4.) It is possible to construct the wave-dissipating block having a Y-shaped cross section so that no gap is formed between adjacent wave-dissipating blocks. However, when the cross-sectional Y-shaped wave-dissipating block is densely stacked in a stable state in a plurality of rows and stages, the lower wave-dissipating block and the wave-dissipating block one level higher than the lower wave-dissipating block are included. It was necessary to invert the top and bottom with the wave block, which required labor for the construction. In addition, the wave hitting the wave-dissipating block may get over the wave-dissipating block and the breakwater behind it to reach the land, similar to the tetrahedral wave-dissipating block.

  Further, a wave-dissipating block (hereinafter referred to as “cross-sectional X-type wave-dissipating block”) in which a cross section perpendicular to the longitudinal direction forms a columnar body having an X shape or an H shape has been proposed (for example, (See FIG. 1 of Patent Document 3, FIG. 1 (II) of Patent Document 4, and FIG. 1 of Patent Document 5). It is also possible to construct a wave-dissipating block having an X-shaped cross section so that no gap is formed between adjacent wave-dissipating blocks. In addition, if the cross-sectional X-shaped wave-dissipating block is vertically symmetrical, the lower wave-dissipating block and the upper wave-dissipating block are inverted upside down even when only the plurality of rows are stacked in multiple rows. It is not necessary to make it, and can be easily constructed. However, the fact that the wave hitting the wave-dissipating block may reach the land over the wave-dissipating block and the breakwater behind it is the same as that of the tetrahedral and Y-shaped wave-dissipating blocks.

JP 05-033320 A Japanese Patent Publication No. 51-022295 Japanese Patent Publication No.52-003219 Japanese Utility Model Publication No. 48-059508 Japanese Utility Model Publication No. 55-013244

  The present invention has been made in order to solve the above-described problems, and not only greatly attenuates the energy of waves that reach a protected object such as a coast, but also has a wave-attenuating block having a structure in which the waves are difficult to get over the upper side. Is to provide. It is also an object of the present invention to provide a wave force attenuation block capable of constructing a tenacious structure such as a breakwater that can be restored to its original state even if it receives a large impact from a strong wave such as a tsunami and temporarily moves. Is the purpose.

The above issues
It has a roughly rectangular parallelepiped shape with front, top, back, bottom, right and left sides,
Vertical width direction intermediate portions on the front surface, upper surface, rear surface, and lower surface (vertical width direction intermediate portions on the front surface and rear surface, and front-back width direction intermediate portions on the upper surface and lower surface) are perpendicular to the left-right direction. Wave force attenuation block (wave-dissipating block) characterized by a concave portion formed in a concave cylindrical surface so that the cross-section becomes an arc shape
Solved by providing.

Here, the terms “front”, “up”, “rear”, “lower”, “right” or “left” are used for convenience to describe the form of the wave power attenuation block of the present invention. As long as any one of the front surface, the upper surface, the rear surface, and the lower surface is directed to face the wave traveling direction, the direction in which the wave force attenuation block of the present invention is installed is not limited. The wave force attenuating block of the present invention can be installed such that its upper surface is directed downward in the vertical direction, or can be installed so that its rear surface faces forward.

  In addition, “having a substantially rectangular parallelepiped shape having a front surface, an upper surface, a rear surface, a lower surface, a right surface, and a left surface” means that the front surface, the upper surface, the rear surface, the lower surface, the right surface, and the left surface of the wave power attenuating block This means that the external shape of the wave power attenuation block has a rectangular parallelepiped shape when ignoring the above and assuming that it is a rectangular plane. Further, the “arc shape” is not limited to a strict “arc shape” but includes a shape that is smoothly curved so as to have an arcuate shape. For this reason, the “concave cylindrical surface shape” is not limited to a strict “concave cylindrical surface”.

  By adopting the above-described configuration of the wave force attenuation block, the surface (hereinafter referred to as “wave receiving surface”) facing the wave traveling direction among the front surface, the upper surface, the rear surface, and the lower surface of the wave force attenuation block. When a wave collides, the wave can be raised along the concave cylindrical surface of the wave receiving surface, and the direction of the wave can be reversed near the water surface. Become. For this reason, it becomes possible to prevent the wave from going over the wave power attenuation block. In addition, the force of waves newly traveling toward the wave receiving surface can be weakened by the flow of water reversed on the wave receiving surface. In the following, this action (effect) by the wave receiving surface may be referred to as “wave force damping action (effect)”.

  Moreover, the wave-power attenuation | damping block of this invention will be in the state by which the overhang | projection part projected outward was formed in the corner | angular part formed by each surface by the recessed part provided in the front surface, the upper surface, the rear surface, and the lower surface. That is, a protruding portion (first protruding portion) that protrudes forward and obliquely upward is formed at the corner portions of the front surface and the upper surface, and an extended portion that protrudes obliquely upward and backward at the corner portions of the upper surface and the rear surface. (Second overhanging part) is formed, and overhanging parts (third overhanging part) that project obliquely downward and rearward are formed at the corners of the rear surface and the lower surface, and at the corners of the lower surface and the front surface. In this state, an overhanging portion (fourth overhanging portion) projecting diagonally forward and downward is formed.

  For this reason, when constructing a structure such as a breakwater by installing a plurality of wave power attenuation blocks in a plurality of rows and stages, the third overhang portion in one wave power attenuation block is connected to the one wave power attenuation block. It is stored in a recess formed on the upper surface of another wave power attenuation block installed on the lower rear side, and the fourth overhang portion of the one wave power attenuation block is placed on the lower front side of the one wave power attenuation block. It becomes possible to fit in the recessed part formed in the upper surface of the other wave power attenuation | damping block installed in. Thereby, it becomes possible to construct a tenacious structure in a state in which the wave force attenuation blocks installed in a plurality of rows and stages are engaged with each other in the front-rear and left-right directions.

  In the wave force attenuating block of the present invention, it is preferable that the front edge portion and the rear edge portion on each of the upper surface and the lower surface are formed in a convex cylindrical surface shape so that a cross section perpendicular to the left-right direction is an arc shape. Thereby, as described above, when installing the plurality of wave force attenuation blocks in a plurality of rows and stages, the tip portions of the first overhanging portion and the second overhanging portion of the lower wave force attenuation block are placed on the upper side. The lower surface of the wave force attenuating block is brought into contact with the concave portion on the lower surface, and the tip portion of the third overhanging portion and the fourth overhanging portion of the upper wave force attenuating block are connected to the upper surface recessed portion of the lower wave force attenuating block. Can be brought into contact with the surface. For this reason, it becomes possible to prevent the wave force attenuation block from being damaged by preventing a local force from being applied to the wave force attenuation block after installation.

  In the wave power attenuation block of the present invention, it is also preferable that the upper edge portion and the lower edge portion on each of the front surface and the rear surface are formed flat. Thereby, when installing a plurality of wave power attenuation blocks in a plurality of rows and stages as described above, the front end portions of the second overhang portion and the third overhang portion in the front wave force attenuation block are arranged on the rear side. It becomes possible to make a surface contact with the front-end | tip part of the 1st overhang | projection part and the 4th overhang | projection part. Therefore, when the force received from the wave in the front row wave attenuation block propagates to the wave attenuation block in the rear row, make sure that no local force is applied to each wave attenuation block. It becomes possible to make it difficult to damage the wave force attenuation block (particularly the overhanging portion).

  Furthermore, in the wave force attenuating block of the present invention, it is also preferable to provide a through-hole penetrating from the central portion of the right surface to the central portion of the left surface. By passing a bar or wire through the through-hole, it is possible to connect the wave force attenuation blocks adjacent in the left-right direction, and the wave force attenuation block can be constructed in a more stable state. When a metal is used as the wire, there is a risk of corrosion due to seawater or the like. Therefore, it is preferable to use a high tension belt or rope. This through hole can also be used for passing a hanging string when the wave power attenuation block is lifted by a crane or the like.

  As described above, according to the present invention, it is possible not only to greatly attenuate the energy of a wave that reaches a protection target such as a coast, but also to provide a wave force attenuation block having a structure in which the wave does not easily get over the upper side. In addition, it is possible to provide a wave attenuation block that can build a tenacious structure such as a breakwater that can be restored to its original state even if it moves temporarily under a strong impact from a strong wave such as a tsunami. Become.

It is the perspective view which showed the wave power attenuation | damping block of this invention. It is the figure which showed the state which looked at the wave power attenuation | damping block of this invention from the front side. It is the figure which showed the state which looked at the wave power attenuation | damping block of this invention from the rear surface side. It is the figure which showed the state which looked at the wave power attenuation | damping block of this invention from the right surface side. It is the figure which showed the state which looked at the wave power attenuation | damping block of this invention from the left surface side. It is the figure which showed the state which looked at the wave power attenuation | damping block of this invention from the upper surface side. It is the figure which showed the state which looked at the wave power attenuation | damping block of this invention from the lower surface side. It is sectional drawing which showed the state cut | disconnected by the plane which bisects the wave power attenuation | damping block of this invention front and back. It is the perspective view which showed the state which piled up and installed the wave power attenuation | damping block of this invention in the multiple rows | lines multiple steps. It is the figure which showed the state which looked from the side of the wave power attenuation | damping block the state which piled up and installed the wave power attenuation | damping block of this invention in multiple rows | lines multiple steps.

[Wave force attenuation block]
Hereinafter, the preferred embodiment of the wave power attenuation block of the present invention will be described more specifically with reference to the drawings. FIG. 1 is a perspective view showing a wave force attenuation block 10 of the present invention. 2-7 is the figure which showed the state which looked at the wave power attenuation | damping block 10 of this invention from the front surface 11 side, the rear surface 13 side, the right surface 15 side, the left surface 16 side, the upper surface 12 side, and the lower surface 14 side, respectively. . FIG. 8 is a cross-sectional view showing a state where the wave force attenuation block 10 of the present invention is cut along a plane that bisects it back and forth (a plane passing through points P ₇ , P ₁₅ , and Q ₇ in FIG. 1). FIG. 9 is a perspective view showing a state in which the wave force attenuation blocks 10 of the present invention are stacked and installed in a plurality of rows and stages. FIG. 10 is a view showing a state in which the wave force attenuation blocks 10 of the present invention are installed in a plurality of rows and stages, as viewed from the side of the wave force attenuation block 10.

  As shown in FIG. 1, the wave force attenuation block 10 of the present invention has a substantially rectangular parallelepiped shape having a front surface 11, an upper surface 12, a rear surface 13, a lower surface 14, a right surface 15 and a left surface 16. As shown in FIGS. 4 and 5, the intermediate portion 11 a in the vertical width direction on the front surface 11 is a first concave portion 18 a formed in a concave cylindrical surface shape so that a cross section perpendicular to the horizontal direction is an arc shape. Yes. Further, the front-rear width direction intermediate portion 12a on the upper surface 12 is a second concave portion 18b formed in a concave cylindrical surface shape so that a cross section perpendicular to the left-right direction is an arc shape. Further, the intermediate portion 13a in the vertical width direction on the rear surface 13 is a third concave portion 18c formed in a concave cylindrical surface shape so that a cross section perpendicular to the horizontal direction is an arc shape. Furthermore, the front-rear width direction intermediate portion 14a on the lower surface 14 is a fourth concave portion 18d formed in a concave cylindrical surface shape so that a cross section perpendicular to the left-right direction is an arc shape.

  Therefore, the wave force attenuating block 10 of the present invention has a first overhanging portion 17a projecting diagonally forward and upward at the corner between the front surface 11 and the upper surface 12, and at the corner between the upper surface 12 and the rear surface 13. The second projecting portion 17b projecting obliquely rearward and upward is formed, and the third projecting portion 17c projecting obliquely rearward and downward is formed at the corner between the rear surface 13 and the lower surface 14, and the lower surface 14 and the front surface 11 are formed. The fourth overhanging portion 17d is formed at the corner portion of the front overhanging diagonally downward. In the following, for convenience of explanation, the first overhanging portion 17a, the second overhanging portion 17b, the third overhanging portion 17c, and the fourth overhanging portion 17d are not distinguished from each other and are expressed as “the overhanging portion 17”. Sometimes. Similarly, the first concave portion 18a, the second concave portion 18b, the third concave portion 18c, and the fourth concave portion 18d may be referred to as “concave portion 18” without being distinguished from each other.

  By the way, in the wave power attenuation block 10 of the present invention, if the front surface 11, the upper surface 12, the rear surface 13 and the lower surface 14, including the recesses 18, are all the same size and shape, the wave force attenuation block 10 can be moved in the front-rear direction. Even if it rolls, it becomes the same state. For this reason, the wave force attenuating block 10 may be installed so that any one of the front surface 11, the upper surface 12, the rear surface 13 or the lower surface 14 thereof becomes the wave receiving surface 10a. be able to. However, in the wave force attenuating block 10 of this embodiment, the front surface 11 and the rear surface 13 have the same size and shape, and the upper surface 12 and the lower surface 14 have the same size and shape, but the front surface 11 (or the rear surface 13). The upper surface 12 (or the lower surface 14) is not the same size and shape.

Specifically, the front edge portion (portion surrounded by points P ₅ , P ₆ , Q ₆ , and Q ₅ in FIG. 1) on the upper surface 12 and the rear edge portion (points P ₈ , P in FIG. 1) on the upper surface 12. ₉ , Q ₉ , Q ₈ ), a front edge on the lower surface 14 (portion surrounded by points P ₁ , P ₁₆ , Q ₁₆ , Q ₁ in FIG. 7), and a front edge on the lower surface 14. The portion (portion surrounded by points P ₁₄ , P ₁₃ , Q ₁₃ , Q ₁₄ in FIG. 7) is formed in a convex cylindrical surface shape so that the cross section perpendicular to the left-right direction is an arc shape. On the other hand, the upper edge portion (portion surrounded by points P ₄ , P ₅ , Q ₅ , and Q ₄ in FIG. 1) on the front surface 11 and the lower edge portion (points P ₁ , P ₂ in FIG. 1) on the front surface 11. , Q ₂ , Q ₁ ), an upper edge on the rear surface 13 (portion surrounded by points P ₉ , P ₁₀ , Q ₁₀ , Q ₉ in FIG. 3), and a lower edge on the rear surface 13. (Parts surrounded by points P ₁₂ , P ₁₃ , Q ₁₃ , and Q ₁₂ in FIG. 3) are formed flat.

  By adopting the above configuration, as shown in FIG. 10, when installing the plurality of wave force attenuation blocks 10 in a plurality of rows and stages, the tip of the overhanging portion 17 in the lower wave force attenuation block 10 is The upper wave force attenuation block 10 is brought into contact with the concave portion 18 on the surface, and the tip portion of the overhang portion 17 in the upper wave force attenuation block 10 is brought into contact with the concave portion 18 in the lower wave force attenuation block 10 on the surface. It becomes possible to let. For this reason, it is possible not only to make the wave attenuation block 10 difficult to break, but also to make a construction such as a breakwater to be constructed persistent. Further, by adopting the above configuration, as shown in FIG. 10, when installing the plurality of wave force attenuation blocks 10 in a plurality of rows and stages, the front end portion of the overhang portion 17 in the wave force attenuation block 10 on the front side. Can be brought into contact with the front end portion of the overhang portion 17 in the wave wave attenuation block 10 on the rear side. For this reason, when the force received from the wave 40 by the wave power damping block 10 in the front row propagates to the wave force damping block 10 in the back row, no local force is applied to each wave force damping block 10. In this way, it is possible to make the overhanging portion 17 of the wave power attenuation block 10 difficult to break.

The dimension of the wave power attenuation block 10 of the present invention is not particularly limited, but if it is too small, a large number of wave force attenuation blocks 10 are required when constructing a structure such as a breakwater, and labor is required for the construction. Become. Further, the individual wave force attenuation blocks 10 become too light, and the wave force attenuation blocks 10 may move due to the pressure received from the water. Furthermore, the size of the wave receiving surface of the wave force attenuating block 10 is inevitably small, and the above-described wave force attenuating action may be difficult to be achieved. For this reason, it is preferable that the individual wave force attenuation blocks 10 have dimensions that allow at least the weight to be about 0.5 t, preferably 1 t or more. For example, the height of the wave attenuation block 10 (the length of the line segment P ₁ P ₅ in FIG. 1; the same applies hereinafter) and the depth (the length of the line segment P ₅ P ₉ in FIG. 1; the same applies hereinafter). .) and width (and that of the length of the line segment _P 1 _{Q 1.} hereinafter the same.) both the 1m in Figure 1, the depth D of the recess 18 (see Figure 1) as a 25 cm, a width W (FIG. 1) is 75 cm, and the density of the concrete forming the wave force attenuation block 10 is 2.3 g / cm ² , the weight of the wave force attenuation block 10 is about 1 t.

On the other hand, if the dimension of the wave force attenuation block 10 is too large, its transportation and construction may be difficult. For this reason, it is preferable that the individual wave force attenuation blocks 10 have dimensions that can suppress the weight to 150 t or less. For example, the height and depth of the wave power attenuation block 10 are both 5 m, the width is 6 m, the depth D of the recess 18 is 125 cm, the width W is 375 cm, and the density of the concrete forming the wave power attenuation block 10 is 2 When the weight is 3 g / cm ² , the weight of the wave force attenuation block 10 is about 150 t. The specific dimensions of the wave power attenuation block 10 are appropriately determined according to the use and construction location of the wave power attenuation block 10. In most cases, the height, depth, and width of the wave power attenuation block 10 are as follows. All are set in the range of 1 to 5 m. The wave force attenuation block 10 of the present embodiment has a height, depth and width of 3 m, and its weight is about 30 t.

As shown in FIG. 1, the first recess 18 a extends in the left-right direction from the right edge to the left edge of the front surface 11 on which the first recess 18 a is provided. The width W of the first recess 18a (see FIG. 1) is appropriately determined according to the height of the wave force attenuation block 10 and the like. There is a possibility that the wave force attenuating action is not easily achieved. For this reason, the width W of the first recess 18a is the ratio W of the width W to the height of the wave attenuation block 10 (the length of the line segment P ₁ P ₅ in FIG. 1; hereinafter referred to as “L ₁ ”). / _{L 1} is preferably set in a range of 0.5 or more. The ratio W / L ₁ is more preferably 0.6 or more, further preferably 0.7 or more, and most preferably 0.75 or more. On the other hand, if the width W of the first recess 18a is too large, the tip end of the first overhanging portion 17a and the tip end of the fourth overhanging portion 17d are inevitably narrowed, and the strength of that portion can be ensured. May be difficult. For this reason, it is preferable that the width W of the first recess 18a is set in a range where the ratio W / L ₁ is 0.95 or less. The ratio W / L ₁ is more preferably 0.9 or less. In the wave force attenuation block 10 of the present embodiment, the height L ₁ of the wave force attenuation block 10 is 3 m, the width W of the first recess 11 a is 2.4 m, and the ratio W / L ₁ is 0. It is eight. Relationship between the depth of the width and wave power attenuation block 10 of the second recess 18b, the relationship between the height L ₁ of the width and wave power attenuation block 10 of the third recess 18c, and the width and wave power attenuation of the fourth recess 18d The same applies to the relationship with the depth of the block 10.

Further, the depth D (see FIG. 1) of the first recess 18a is appropriately determined according to the depth of the wave force attenuation block 10 and the like, but if it is too shallow, the curvature at the portion 11a of the front surface 11 is small ( When the front surface 11 becomes a wave receiving surface, the above-described wave force attenuation action may not be suitably achieved. For this reason, the depth D of the first recess 18a is the ratio of the depth D to the depth of the wave power attenuation block 10 (the length of the line segment P ₅ P ₉ in FIG. 1; hereinafter, expressed as “L ₂ ”). It is preferable that D / L ₂ is set within a range of 0.1 or more. The ratio D / L ₂ is more preferably 0.15 or more, and further preferably 0.2 or more. On the other hand, if the depth D of the first recess 18a is too deep, it may be difficult to secure the strength of the wave force attenuation block 10. For this reason, it is preferable to set the depth D of the first recess 18a in a range where the ratio D / L ₂ is 0.4 or less. The ratio D / L ₂ is more preferably 0.35 or less, and further preferably 0.3 or less. In the wave force attenuation block 10 of the present embodiment, the depth L ₂ of the wave force attenuation block 10 is 3 m, the depth D of the first recess 11a is 75 cm, and the ratio D / L ₂ is 0.25. It has become. Relationship between the height L ₁ of the depth and wave power attenuation block 10 of the second recess 18b, the relationship between the depth L ₂ of the depth and wave power attenuation block 10 of the third recess 18c, and the depth and wave of the fourth recess 18d the same applies to the relationship between the height L ₁ of the force attenuating block 10.

  The wave damping block 10 of the present invention is made of concrete. The kind of concrete to be used is not particularly limited. In addition to ordinary concrete, various types of concrete can be used, such as heavy concrete using aggregate with a large specific gravity and high-strength concrete with reduced internal bubbles. The wave force attenuating block 10 of this embodiment is also formed by placing concrete on a mold and curing it. The wave force attenuation block 10 may have a reinforcing bar in its interior, but in this case, problems such as cracks due to the difference in thermal expansion coefficient between the concrete and the reinforcing bar and corrosion of the reinforcing bar occur. Therefore, it is preferable not to arrange reinforcing bars inside. However, reinforcing bars can be arranged if measures are taken to solve these problems.

  The mold forming the wave attenuation block 10 includes a mold forming the front surface 11 (first mold), a mold forming the upper surface 12 (second mold), and a mold forming the rear surface 13 ( The third mold frame) and the mold frame (fourth mold frame) forming the lower surface 14 are separable from each other, and the first mold frame, the second mold frame, the third mold frame, and the fourth frame that are set up vertically. It is preferable to manufacture the wave damping block 10 by placing concrete in a space surrounded by a mold and curing it. Thereby, even if it does not form the front surface 11, the upper surface 12, the rear surface 13, and the lower surface 14 of the wave power attenuation | damping block 10 in a taper shape, it is possible to punch out easily. In addition, it is possible to increase the strength and durability of the obtained wave force attenuation block 10 by making it difficult for bubbles to be generated on the concrete surface.

  Further, in the wave force attenuating block 10 of the present embodiment, as shown in FIGS. 1 and 8, a through-hole 19 that penetrates from the center of the right surface 15 to the center of the left surface 16 is provided. A rod or wire (not shown) can be passed through the through hole 19. The bar or wire passed through the through-hole 19 makes it possible to connect the wave force attenuation blocks 10 adjacent to each other in the left-right direction after construction, and to lift the wave force attenuation block 10 with a crane or the like. . The inner diameter of the through-hole 19 varies depending on the dimensions of the wave power attenuation block 10 and the like, but is usually about 5 to 20 cm, preferably about 10 to 15 cm.

  Each of the surfaces 11 to 16 of the wave force attenuation block 10 may be a smooth surface, but among these, the front surface 11 and the rear surface 13 (the upper surface 12 and the lower surface 14 as necessary) that may be a wave receiving surface are: It is also preferable to roughen the surface. The roughening of the wave force attenuation block 10 may be realized by a mold, or may be realized after die cutting, such as applying a special coating to the surface of the wave force attenuation block 10 after die cutting. As a result, resistance can be imparted to water flowing in the vicinity of the wave receiving surface (particularly, water flowing to the left and right in the vicinity of the wave receiving surface), and the flow of water can be weakened. This configuration is preferably employed when the wave force attenuation block 10 is used for revetment of a flowing waterway such as a river. The surface of the wave power attenuation block 10 can be waterproofed so that water does not soak into it.

[Usage]
The wave power attenuating block 10 of the present invention can be used not only for installing on the sea side of an existing breakwater, but also for raising an existing breakwater or building a new breakwater by itself. . It can also be used to build submersibles. In the upward concave portion 18 of the wave-attenuating block 10 after installation, as shown in FIG. 10, a fill 30 can be applied and used for vegetation. In addition, gravel stone, concrete or asphalt (not shown) is poured into the upward concave portion 18 of the wave power attenuation block 10 (particularly, the wave power attenuation block 10 located at the uppermost stage) after the construction, and the portion is made flat. It can also be a road. Further, the space 10e formed by the concave portion 18 of the wave power attenuation block 10 can be used as a fishing reef space. Since the wave force attenuation block 10 of the present invention is provided with the recesses 18 on the respective surfaces 11 to 14, it can have various functions after construction.

[effect]
Finally, the effect of the wave force attenuation block 10 of the present invention will be described.
-Wave force attenuation effect First, the wave force attenuation effect | action by the wave-receiving surface 10a of the wave force attenuation block 10 of this invention is demonstrated. As shown by the arrows A and B in FIG. 10, the wave force attenuation block 10 after the construction, when the wave 40 collides with the wave receiving surface 10 a, the wave 40 is curved along the wave receiving surface 10 a. The direction of the wave 40 can be reversed (wave force can be reversed). For this reason, it is possible to prevent the wave 20 from going over the structure formed by the wave power attenuation block 10. In addition, it is possible to weaken the force of the wave newly traveling toward the wave receiving surface 10a with the flow of water inverted by the wave receiving surface 10a (to exhibit a wave force damping action). In addition, the wave receiving surface 10a of the wave force attenuation block 10 that is arranged in the lower stage and is entirely below the water surface can also exhibit an action similar to the wave force attenuation action.

-Construction of a tenacious structure Moreover, when the wave power attenuation block 10 of the present invention is used, a tenacious structure can be constructed. This is because when the structure constructed by the wave force attenuation block 10 receives a large impact from a strong wave such as a tsunami, each wave force attenuation block 10 is temporarily moved by the pressure from the wave 40, but it is overhanging. This is because the portion 17 is in a state of being accommodated in the concave portion 18, so that after the pressure disappears, the original state is naturally restored. That is, in the wave force attenuation block 10 of the present invention, as shown in FIG. 10, the entire structure is united and the structure is persistently maintained by the resistance force (self-weight × distance from the fulcrum). This effect is more remarkably achieved by curving the tip of the overhanging portion 17 in an arc shape along the concave portion 18. On the other hand, for example, when cubic blocks are arranged in a plurality of rows and stages with no gaps, gaps are formed between the blocks after the pressure disappears. As you repeat this, the structure of cubic blocks will be destroyed.

-Damage prevention due to overflow One of the main causes of breakage of a breakwater due to a tsunami, etc., is that the wave overflowing the breakwater hits the ground behind the breakwater and digs up the ground. However, when a structure as shown in FIG. 10 is constructed by the wave power attenuation block 10 of the present invention, the wave that has overflowed is received by the overhanging portion 17 obliquely upward in the rearward direction of the wave force attenuation block 10 arranged in the last row. The wave force hitting the ground on the back side of the structure can be weakened. Therefore, in the wave power attenuation block 10 of the present invention, it is possible to prevent damage due to the overflow of the structure.

Others The wave power attenuation block 10 of the present invention can not only reduce the manufacturing cost, but also can suppress the ground improvement cost when installing it to construct a structure. That is, in the case where a structure having a trapezoidal cross section is constructed by placing concrete on site, and in the case where the structure is constructed by stacking the wave force attenuation blocks 10 of the present invention as shown in FIG. However, since the total weight of the concrete is light, it is possible to simplify the ground improvement work or, in some cases, to construct a structure without performing the ground improvement work.

DESCRIPTION OF SYMBOLS 10 Wave-power attenuation | damping block 10a Wave receiving surface 10b Upward surface 10c Backward surface 10d Downward surface 10e Fishing reef space (space formed by a recessed part)
11 Front surface (surface area P ₁ P ₅ Q ₅ Q ₁ )
11a Middle part in the vertical width direction on the front surface (surface region P ₂ P ₄ Q ₄ Q ₂ )
12 Upper surface (surface region P ₅ P ₉ Q ₉ Q ₅ )
12a Middle portion in the front-rear width direction on the upper surface (surface region P ₆ P ₈ Q ₈ Q ₆ )
13 rear surface (surface region P ₉ P ₁₃ Q ₁₃ Q ₉ )
Vertical width direction intermediate portion of 13a rear surface (surface area _{P 12 P 10 Q 10 Q 12} )
14 Lower surface (surface region P ₁₃ P ₁ Q ₁ Q ₁₃ )
Width direction intermediate portion in the anteroposterior 14a lower surface (surface area _{P 16 P 14 Q 14 Q 16} )
15 Right side (plane area P ₁ P ₅ P ₉ P ₁₃ )
16 Left side (plane area Q ₁ Q ₅ Q ₉ Q ₁₃ )
17 overhang portion 17a first overhang portion 17b second overhang portion 17c third overhang portion 17d fourth overhang portion 18 recess 18a first recess 18b second recess 18c third recess 18d fourth recess 19 through hole 20 Construction surface 30 Fill 40 waves

Claims (4)

A wave force attenuating block having a substantially rectangular parallelepiped shape having a front surface, an upper surface, a rear surface, a lower surface, a right surface, and a left surface, and being installed such that any of the front surface, the upper surface, the rear surface, or the lower surface is a receiving surface. ,
The middle part in the vertical width direction on each of the front surface, upper surface, rear surface, and lower surface is a concave cylindrical surface extending in the left-right direction from the right edge to the left edge of each surface so that the cross section perpendicular to the left-right direction is an arc shape Rutotomoni is a recess formed,
The ratio of the width of the recess provided on the front surface to the height of the wave power attenuation block, the ratio of the width of the recess provided on the upper surface to the depth of the wave power attenuation block, provided on the rear surface relative to the height of the wave power attenuation block A wave force attenuating block characterized in that the ratio of the width of the recessed portion and the ratio of the width of the recessed portion provided on the lower surface to the depth of the wave power attenuating block are both 0.5 or more .   The wave force attenuation block according to claim 1, wherein the front edge portion and the rear edge portion on each of the upper surface and the lower surface are formed in a convex cylindrical surface shape so that a cross section perpendicular to the left-right direction is an arc shape.   3. The wave force attenuating block according to claim 1, wherein the upper edge and the lower edge of each of the front surface and the rear surface are formed flat.   The wave force attenuation block according to any one of claims 1 to 3, wherein a through-hole penetrating from a central portion of the right surface to a central portion of the left surface is provided.

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