JP5427867B2 - Tsunami countermeasure shore structure - Google Patents

Description

  The present invention relates to a coastal structure such as a coast or a riverbank constructed for tsunami countermeasures that attenuates tsunami energy.

  As a preventive measure against tsunami damage that is generally performed in Japan, a breakwater is constructed. In constructing the breakwater, the height of the top and the strength of the chest wall are determined based on the scale of the past tsunami, thereby preventing overtopping and preventing damage such as settlement due to the tsunami run-up.

  However, a breakwater with a high crest height and a strong chest wall has a large bottom surface, which makes the entire structure large-scale and construction costs huge. Breakwaters with high tops are not only impaired in view from the land side, and the living environment of local residents is not only impaired, but also a problem in tourism resources. In particular, when a tsunami occurs, visibility to the tsunami is also reduced, which may cause evacuation delays for local residents.

  As recently proposed breakwaters, for example, a multistage breakwater is constructed in the sea so that the energy of the tsunami is attenuated before the tsunami reaches the land (see Patent Document 1 below), or concrete. A chest wall is constructed using a cellular made of steel, and a number of pillars and culverts are provided at the bottom of the breakwater, making it easy for seawater to enter and exit, while a steel door is installed in the culvert to prevent tsunami intrusion. (See Patent Document 2 below).

JP-A-7-113219 JP 2007-63896 A

  However, since these are all directly receiving the energy of a large tsunami, the breakwater itself must have a considerable strength. It will be built by using a huge amount of money and labor. In the latter case, the visibility is not sufficient, and the living environment and tourism resources of local residents are impaired.

  The present invention has been made to solve the above-described problems. Before the tsunami goes up to the land, the energy of the tsunami is greatly attenuated to prevent the tsunami going up as much as possible from affecting the breakwater. The purpose is to provide a shore structure for tsunami countermeasures that can be quickly constructed while reducing the material cost required for construction, while reducing the top height of the breakwater and ensuring visibility or living environment .

The tsunami countermeasure shore structure of the present invention that achieves the above object is formed by drilling the ground surface, and has a concave groove portion that allows the tsunami to fall inside, and at least the sea side edge of the concave groove portion. is formed, it possesses a raised part which drop height is set higher tsunami, and is characterized in that formed at least on the sea side of the breakwater formed along a concave groove on the bank.

  According to the first aspect of the present invention, the concave groove is formed by drilling the ground surface, and the tsunami that goes up to the land is allowed to freely fall into the concave groove, and once in the vertical direction or toward the ground Since it is directed in the lateral direction along the direction of the tsunami, the energy of a large tsunami can be significantly attenuated, and the situation where the tsunami reaches the village directly can be avoided or delayed.

Also, since the forming raised portions on the edge of at least the ocean side of the concave groove, drop height of the tsunami is increased, it is possible to attenuate the good Rie energy. In particular, when the raised portion is constructed by using waste soil generated by forming the concave groove portion, it can be molded without requiring a new material, which is advantageous in terms of cost. In addition, since the concave groove portion is formed at least on the sea side of the breakwater, primarily, the tsunami is dropped into the concave groove portion to attenuate the energy of a large tsunami, and the tsunami energy directly affects the breakwater. Therefore, the arrival of the tsunami can be avoided or delayed as much as possible. Secondarily, since the breakwater does not receive tsunami energy directly, the strength and top height of the breakwater can be suppressed as much as possible, visibility and living environment can be secured to some extent, and tourism resources can be damaged. Absent. Furthermore, when there is an existing breakwater, a concave groove may be formed in the vicinity thereof, and a tsunami countermeasure can be constructed quickly and at low cost.

  According to the second aspect of the present invention, the side wall, the bottom surface, and the surface of the raised portion of the concave groove portion are covered with the sheet member, so that the strength of the concave groove portion and the periphery thereof is improved and the tsunami does not collapse. The shape and structure of the concave groove can be maintained over a long period of time.

According to invention of Claim 3 , since the said concave groove part was also formed in the land side of a breakwater, in addition to the effect mentioned above, when the tsunami which wave-passed the said breakwater falls freely into a concave groove part, further tsunami It is possible to avoid or delay the situation of reaching the village directly. In addition, it is possible to prevent everything from flowing into the sea due to the tsunami, which makes it possible to preserve or secure a certain amount of property and prevent marine pollution.

According to invention of Claim 4 , a sheet | seat member seals the interior member formed by mixing a fiber and a cement material with the surface member which can permeate | transmit water, and a non-water-permeable back surface member. Since it is constituted by the formed concrete sheet, after covering and fixing the side wall and the raised portion of the concave groove portion with the concrete sheet, the concrete sheet can be solidified only by watering the concrete sheet, and the concave groove portion etc. A strong protective wall can be constructed easily and quickly. In addition, the concrete sheet is less prone to cracking and less deteriorated, so that the durability of the concave groove is improved. Moreover, since a concrete sheet can be conveyed easily, construction of a concave groove part can be performed very rapidly.

According to invention of Claim 5 , since the wave-dissipating block was arrange | positioned inside the said concave groove part, the momentum of the tsunami which flowed into the inside of the concave groove part can be reduced also with a wave-dissipating block, and tsunami energy is further attenuated be able to.

According to the sixth aspect of the present invention, since the wave-dissipating block is made of Pokhara, the tsunami force that flows inside Pokhara can be reduced.

According to the seventh aspect of the present invention, since the Pokhara is arranged in a stepped shape, a flow in which the tsunami rises along the stepped Pokara can be generated inside the concave groove, and the tsunami energy can be generated by the generation of this rising flow. The tsunami energy can be attenuated not only by damaging the tsunami, but also by the mutual collision between the newly falling tsunami and the rising flow.

According to the eighth aspect of the present invention, since the reservoir for storing deposits is formed at the bottom of the concave groove, the depth of the concave groove is maintained for a long time even when sand or wood chips enter the concave groove. be able to.

According to the ninth aspect of the present invention, when a part of the upper surface of the concave groove portion is covered with a cover member such as a net, a bridge or a lid, even if a large concave groove portion is formed, the residents of the area There will be no disruption to life.

1 is a schematic plan view showing a first embodiment of the present invention. It is a schematic sectional drawing in alignment with line 2-2 in FIG. It is a principal part expanded sectional view of FIG. It is sectional drawing of a sheet | seat member. It is a principal part schematic sectional drawing which shows 2nd Embodiment of this invention. It is a schematic perspective view which shows an example of Pokhara. It is a principal part schematic sectional drawing which shows 3rd Embodiment of this invention. It is a schematic sectional drawing which shows 4th Embodiment of this invention.

  Embodiments of the present invention will be described below with reference to the drawings.

(First embodiment)
A tsunami countermeasure shore structure 10 according to the present embodiment is constructed on a shore 13 such as a coast 11 or a river shore 12 as shown in FIG. 1, and is formed by drilling a ground surface along the shore 13. The concave groove part 20 is configured to drop a tsunami inside, and the raised part 30 is formed at the edge of the concave groove part 20 on the sea side.

  In the figure, “14” is a tree, “15” is a road, “16” is a bridge provided in the concave groove 20, and “17” is a breakwater.

  The concave groove 20 is preferably provided in the vicinity of the seaside of the breakwater 17, that is, at a position spaced a predetermined length from the breakwater 17 to the seaside. The breakwater 17 may be any type. For example, as shown in FIG. 2, the breakwater 17 includes a foundation portion 17 a erected from a bedrock and a chest wall 17 b provided on the foundation portion 17 a. It is configured. The shape of the chest wall 17b is not limited to an upright wall as illustrated, but may be any shape such as a transclined wall or an overhanged shape.

  The concave groove 20 should determine the width W and depth D according to the topography of the site, the location conditions, or the expected tsunami scale, but how much it delays the time for the tsunami to reach the village or building directly. Moreover, it is preferable to consider.

  If the concave groove 20 has a very large width W, for example, a unit of several hundred meters or several kilometers, one or a plurality of small concave grooves 20 are formed in parallel to each other inside the concave groove 20, The tsunami may be allowed to fall freely in multiple stages, or a public building such as a park or road may be provided as necessary to function as a resistor against the tsunami.

  The depth D of the concave groove 20 should be as shallow as possible in view of convenience and danger in daily life, and is preferably about several tens of meters at most.

  The formation of such a concave groove 20 is a problem with waste soil treatment, although it depends on the construction scale. In the present embodiment, this is used for forming the raised portion 30 at the edge of the concave groove portion 20.

  As shown in FIGS. 2 and 3, the raised portion 30 is preferably formed at the sea-side edge of the recessed groove portion 20. In this way, the tsunami (indicated by the solid line arrow in FIG. 3) has to move over the raised portion 30 and the height of the raised tsunami increases, so the height of the tsunami free fall increases. The formation of the raised portion 30 can also attenuate the tsunami energy.

  It is preferable to form the raised portion 30 so as to be a slope that slopes upward from the sea side toward the land side. With such a slope, the tsunami energy can be attenuated while smoothly guiding the tsunami to the concave groove portion 20, and the raised portion 30 can be easily formed, which is preferable from the viewpoint of waste soil treatment and cost.

  Further, the shape of the slope of the raised portion 30 may be a simple slope having a constant angle θ1 from the start end to the end, but as shown in FIG. It is also possible to change the inclination angle in a multistage manner. In some cases, it may be stepped.

  However, in the case of the raised portion 30 formed simply by piling up waste soil, the strength is weak against tsunami. For this reason, in the present embodiment, not only the surface of the raised portion 30 but also the side wall and the bottom wall of the concave groove portion 20 are covered with the sheet member 31.

  Any sheet member 31 may be used, but the use of a concrete sheet, which will be described later, is preferable in terms of installation workability or reinforcement on the side wall of the concave groove 20 or the like.

Here, as shown in FIG. 4, the concrete sheet includes an interior member 34 formed by mixing the fibers 32 and the cement material 33 by a surface member 35 capable of passing water and a non-water-permeable back member 36. It is formed by sealing. Further details will be described. The concrete sheet is formed by stacking a water-permeable surface member 35 and a non-water-permeable back member 36 and stitching the outer peripheral surface thereof to form a bag-like member, and the interior member 34 is accommodated in the bag-like member. And sealing, and the whole is formed flat. The surface member 35 may be anything as long as it is configured so that water or seawater supplied from the outside is soaked into the inside. For example, it is preferable to use a thin fiber material made of woven fiber or non-woven fabric, but for the purpose of increasing strength, an aramid sheet such as Vectran ^TM or Kevlar ^TM may be used. As the back surface member 36, any material may be used as long as it is configured so that water or seawater that has penetrated into the inside through the surface member 35 does not leak to the outside. For example, it is preferable to use a thin-walled material made of a synthetic resin sheet or a cloth coated with a synthetic resin such as polyvinyl chloride. Some Spectra ^™ , Dyneema ^™, etc. may be used. The interior member 34 is a mixture of three-dimensional fibers 32 and a cement material 33, and is combined with water or seawater supplied from outside to solidify to form a concrete wall.

  The concrete sheet may have any size, but considering the ease of handling, the thickness t is 3 mm to 20 mm, the width is 0.5 m to 3 m, and the length is about 10 m to 20 m. Is preferred. With this size, the weight before supplying water or seawater, that is, the weight before curing is about 5 kg / m 2 to 20 kg / m 2 and covers the inner surface of the concave groove 20 and the surface of the raised portion 30. There is no problem in workability when using.

  Here, specific examples of the concrete sheet 10 are shown in A, B, and C below.

  Here, the Mohs hardness means a hardness that can be damaged by a knife. For example, in the case of concrete, the Mohs hardness is about 3 to 7.

  The concave groove 20 may accumulate deposits such as leaves and sand on the bottom. For this reason, in this embodiment, it is preferable to form the bottom part of the concave groove part 20 in V shape, and to form the storage part 37 which stores a deposit here, as shown with a dashed-dotted line in FIG. If such a storage part 37 is formed, even if a leaf, sand, etc. enter the concave groove part 20, it is easy to remove, and the depth D of the concave groove part 20 can be maintained over a long period of time.

  Further, the concave groove portion 20 may be covered with a cover member 38 as shown by a one-dot chain line in FIG. 3 so as not to cause a human accident or the like in a normal state. In consideration of the characteristics, a bridge 16 or a staircase, or an elevator may be provided.

  Next, the operation will be described.

  First, in order to construct the shore-side structure 10 for tsunami countermeasures, the width W and the depth D are determined according to the topography of the site, the location conditions, or the expected tsunami scale, and the shore 13 is separated from the shore 13 by a predetermined distance. The ground at the position is excavated to form a concave groove 20 having a rectangular cross section.

  When such a concave groove portion 20 is formed, a large amount of waste soil is generated. This waste soil is used for raising the edge of the concave groove portion 20 on the sea side to form the raised portion 30. The raised portion 30 is a tapered surface that gradually rises from the sea side toward the land side.

  And the sheet member 31 which consists of concrete sheets is affixed on the surface of the raising part 30, the side wall and bottom wall of the concave groove part 20, and is fixed using a nail or an anchor bolt. After this fixing, water is sprinkled on the surface member 35 of the concrete sheet, the concrete sheet is solidified, and the concave groove portion 20 and the raised portion 30 are reinforced by the concrete sheet.

  When the concave groove portion 20 is formed, the breakwater 17 is formed along the concave groove portion 20 at a position spaced apart from the concave groove portion 20 to the land side by a predetermined method. The breakwater 17 is formed by providing a base portion 17a on the bedrock and standing a chest wall 17b on the base portion 17a.

  When a tsunami goes up toward the shore structure 10 constructed in this way, the tsunami first climbs the raised portion 30 that is an inclined surface that rises from the sea side of the raised portion 30 toward the land side. . Due to the slope of the raised portion 30, the energy of the tsunami is smoothly attenuated toward the concave groove portion 20 while being attenuated to some extent.

  The tsunami that has climbed over the raised portion 30 falls into the concave groove 20 and is redirected from the direction toward the shore 13 to the underground direction or the lateral direction along the coast. Due to this fall and change of direction, the energy of the tsunami is greatly attenuated and the power is killed. Moreover, since the tsunami that has reached the bottom of the concave groove 20 and has been changed in the lateral direction collides with a newly falling one, the tsunami energy is also greatly attenuated. As a result, in the concave groove portion 20, the energy of the tsunami is greatly attenuated due to a change in the flow direction, mutual collision, generation of a vortex flow, and the like.

  In the concave groove 20, since the sheet member 31 made of a concrete sheet is provided on the side wall and the bottom wall, the sheet member 31 is not damaged or peeled off even when the tsunami falls into the concave groove 20. The above-described tsunami energy attenuation effect can be reliably exhibited.

  When the inside of the concave groove portion 20 is filled with seawater and a tsunami goes in the shore direction, the breakwater 10 provided in the vicinity of the concave groove portion 20 prevents this. However, since the energy of the tsunami is greatly attenuated, the breakwater 10 can easily prevent the tsunami from going up.

  In addition, there is a case where a huge tsunami more than expected occurs and the tsunami goes up beyond the breakwater 10, but in this case, the breakwater 10 of this embodiment is not unnecessarily high. The residents of the village can easily see the tsunami run-up, and as a result, the start of evacuation can be prevented.

(Second Embodiment)
FIG. 5 is a schematic cross-sectional view showing the main part of the second embodiment of the present invention, and FIG. 6 is a schematic perspective view showing an example of Pokhara. To do.

  In the tsunami countermeasure shore structure 10 of the present embodiment, wave-dissipating blocks 40 are stacked along the sea side wall of the concave groove 20. As the wave-dissipating block 40, it is preferable to use a Pokhara 41 as shown in FIG. Pokhara 41 is a cube-shaped hollow concrete wave-dissipating block, with through-holes 42 opened on the six sides of the cube. Seawater can easily enter the inside, and tsunami energy into which a large amount of seawater flows Is optimal for attenuating the vibration, and is preferable in terms of workability for installation.

  If such Pokhara 41 is fixedly connected to the side wall and the bottom wall of the concave groove portion 20 provided with the sheet member 31 with anchor bolts or the like, and these are connected to each other with bolts or the like, the characteristics of Pokhara 41 are The tsunami can be introduced from the inside, killing the tsunami momentum and attenuating the tsunami energy.

  That is, when the tsunami goes up toward the concave groove portion 20 constructed in this way, the tsunami first attenuates the energy of the tsunami to some extent by the slope of the raised portion 30, as in the first embodiment, and It falls into the concave groove 20 and its energy is greatly attenuated.

  At the time of this fall, in this embodiment, a tsunami flows into the inside of the Pokhara 41, kills the momentum of the tsunami, and attenuates the tsunami energy. Moreover, when the seawater which fell to the concave groove part 20 raises the inside of the concave groove part 20, it flows in the Pokhara 41, and the energy is further attenuated. In addition, when the Pokhara 41 is stacked stepwise from the bottom surface of the concave groove portion 20, a part of the tsunami moves along the Pokhara 41 and a vortex is generated. The tsunami energy is also attenuated by the generation of this eddy current, but this vortex current collides with the tsunami flow that has newly fallen into the concave groove portion 20, so that the newly dropped tsunami energy Is attenuated.

  In addition, when the inside of the concave groove portion 20 is filled with seawater and a tsunami goes in the shore direction, the breakwater 10 provided in the vicinity of the concave groove portion 20 prevents this as in the first embodiment described above. It will be.

  However, if the place where the tsunami countermeasure shore structure 10 of the present embodiment is installed is a place where only a small tsunami goes up, it is not always necessary to connect the Pokharas 41 to each other. Further, not only the above-described Pokhara but also a wave-dissipating block such as a so-called tetrapot may be used.

(Third embodiment)
FIG. 7 is a schematic cross-sectional view of a main part showing a third embodiment of the present invention. Members common to the above-described members are given the same reference numerals, and description thereof is omitted. In the embodiment described above, the concave groove 20 is provided on the sea side of the breakwater 17. However, in the present embodiment, as shown in FIG. 7, the land is formed on the land side of the breakwater 17 formed along the shore 13. Also, the concave groove 20 is formed. In addition, in FIG. 7, the concave groove part 20 currently formed in the sea side is abbreviate | omitted.

  The concave groove portion 20 formed on the land side is different from the concave groove portion 20 formed on the sea side in the raised portion 30. The raised portion 30 of the present embodiment is formed on the land side edge portion of the concave groove portion 20. That is, the raised portion 30 is formed so that the land side wall of the recessed groove portion 20 is higher than the sea side wall, and even if seawater that has waved over the breakwater 17 enters the recessed groove portion 20, it is difficult for the raised portion 30 to flow to the land side. doing.

  Further, when a tsunami that goes up to the land side beyond such a raised portion 30 is drawn, the land side is placed below the raised portion 30 so that it smoothly returns into the concave groove portion 20 without being disturbed by the raised portion 30. And a drainage channel 39 that passes through the concave groove 20 is provided.

  Since the present embodiment configured as described above has the concave groove 20 on both the sea side and the land side of the breakwater 17, the tsunami caused by the sea-side concave groove 20 and the breakwater 17 is the same as the previous embodiment. In addition to demonstrating the energy attenuating action, the concave groove portion 20 formed on the land side will also exhibit the same tsunami energy attenuating action, and together they will attenuate a large tsunami energy. .

  Further, when a tsunami that goes up to the land side beyond the concave groove portion 20 and the raised portion 30 formed on the land side is drawn, the seawater is not disturbed by the raised portion 30, and the dewatered flow path 39 is not disturbed. It smoothly passes back to the concave groove 20.

(Fourth embodiment)
FIG. 8 is a schematic cross-sectional view showing a fourth embodiment of the present invention, and members common to the members described above are denoted by the same reference numerals and description thereof is omitted.

  In the above-described embodiment, waste soil is used to form the raised portion 30. However, when a large amount of waste soil is discharged, not only this but also the construction of the road 15 is used. May be prevented from going up.

  For example, as shown in FIG. 8, a first concave groove 20a having a water drainage channel 39 is formed on the land side of the breakwater 17 as in the third embodiment described above, and a predetermined distance is formed from the first concave groove 20a to the land side. The second concave groove 20b and the road 15 are formed at positions separated by a distance. In this case, the second concave groove 20b is preferably formed on the sea side of the road 15. However, although it is not always necessary to provide the raised portion 30, it is preferable to provide the above-described concrete sheet that is the sheet member 31 on the side wall of the second concave groove portion 20 b or the side surface of the road 15.

  In this embodiment configured in this way, in addition to the functions of the third embodiment described above, a tsunami energy attenuation function by the second concave groove 20b and a breakwater function of the road 15 itself are added. Excellent tsunami countermeasure shore structure.

  In the present embodiment, since the road 15 is constructed using waste soil discharged in large quantities, the road 15 functions as a coastal conservation facility that persistently opposes the tsunami or as multiple protection. In particular, if both the breakwater 17 and the road, which is a traffic infrastructure, are utilized as tsunami countermeasures, a so-called double levee can be provided in the area, which is an excellent tsunami countermeasure.

  The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims. For example, in the embodiment described above, the concave groove 20 is formed only on the sea side or on the land side and the sea side, but it goes without saying that it may be formed only on the land side.

  The present invention can be used as a tsunami countermeasure shore structure that attenuates tsunami energy.

10: Tsunami countermeasure shore structure,
13 ... Kishibe,
15 ... Road,
16 ... the bridge,
17 ... Breakwater,
20 ... concave groove,
30 ... Raised part,
31 ... sheet member,
32 ... fiber,
33 ... cement material,
34. Interior members,
35 ... surface member,
36 ... Back member 39 ... Drain channel,
40 ... wave-dissipating block,
41 ... Pokhara.

Claims (9)

It is formed by drilling the ground surface along the shore, and is formed in the concave groove part that allows the tsunami to fall inside, and at least the edge of the concave groove part on the sea side, and the drop height of the tsunami is high becomes way was closed and the additional section, the tsunami countermeasure shore structure, characterized in that said concave surface is formed at least on the sea side of the breakwater formed along the shore.   2. The tsunami countermeasure shore structure according to claim 1, wherein a side wall and a bottom surface of the concave groove and a surface of the raised portion are covered with a sheet member.   The concave groove is formed on the land side of the breakwater formed along the shore, and the raised portion is formed on the land-side edge of the concave groove, and the water that has run up to the raised side on the land side. The tsunami countermeasure shore structure according to claim 1 or 2, wherein a water drainage channel is formed to return the water into the concave groove.   The sheet member is composed of a concrete sheet formed by sealing an interior member formed by mixing fibers and cement material with a water-permeable surface member and a non-water-permeable back member. The shore structure for tsunami countermeasures according to claim 2.   The tsunami countermeasure shore structure according to any one of claims 1 to 4, wherein a wave-dissipating block is disposed inside the concave groove.   The tsunami countermeasure shore structure according to claim 5, wherein the wave-dissipating block is made of Pokhara.   The shore structure for tsunami countermeasures according to claim 6, wherein the Pokhara is arranged in a stepped manner in the receiving portion of the concave groove portion.   The tsunami countermeasure shore structure according to any one of claims 1 to 7, wherein the concave groove portion forms a storage portion for storing deposits at a bottom portion.   The tsunami countermeasure shore structure according to any one of claims 1 to 8, wherein the entire upper surface or a part of the concave groove is covered with a cover member.

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