JP5357221B2 - Embankment device or embankment structure using this embankment device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bank device or a bank structure which is capable of damming a large-scaled fluid such as tsunami, muddy stream, pyroclastic flow or others caused by natural phenomena while utilizing power of the large-scaled fluid. <P>SOLUTION: A bank device comprises: a base plate 2 which is fixed on a construction site L; and a rotation member 3 which is arranged on a top face of the base plate 2 and connected rotatable to the base plate 2, and with which a pressure receiving surface 7a receiving the pressure of a large-scaled fluid is formed on a front surface and an abutting part 2a abutting either to the base plate 2 or to the construction site after rotation is formed at a back side. Regarding the rotation member 3, a length from the pressure receiving surface 7a to the abutting part 2a is longer than a height of the pressure receiving surface 7a. When the pressure of the fluid acts on the pressure receiving surface 7a, the rotation member 3 is rotated at a predetermined angle, so that a height of the rotation member 3 is increased, the abutting part 2a is abutted either to the base plate 2 or to the construction site L and the state of the rotation member 3 after the rotation is maintained. <P>COPYRIGHT: (C)2013,JPO&amp;INPIT

Description

  The present invention relates to an embankment device installed to prevent the flow of fluid caused by natural disasters such as a tsunami or pyroclastic flow or to reduce the speed thereof, or to an embankment structure using this embankment device.

  The occurrence of pyroclastic flows caused by tsunamis and volcanic eruptions caused by earthquakes causes catastrophes, and various proposals have been made to prevent such catastrophes. As countermeasures against tsunamis, those that raise the movable wall using water pressure (see Patent Documents 1 and 2) have been proposed, and there are also water-stop facilities or tsunami breakwaters that have a structure that stands up around the axis due to the tsunami. It has been proposed (see Patent Documents 3 and 4). Each of the technologies disclosed in Patent Documents 1 and 2 above is provided on the coast and forms a passage through which seawater flows by the occurrence of a tsunami, and the movable wall or moving column is formed by the water pressure of the seawater that has entered the passage. It is a structure that rises, and it is intended to prevent the tsunami from entering the inside of the levee by this raised movable wall or moving column. On the other hand, the techniques disclosed in Patent Documents 3 and 4 are provided with a string or rope for maintaining a standing state while disposing a waterstop plate on the embankment or in the vicinity thereof so as to be able to fall and stand. The tsunami force causes the waterstop plate that had fallen until then to stand up, and this standing state is held by the chain or rope. In the technologies disclosed in these Patent Documents 3 and 4, when seawater is drawn again into the sea after the tsunami invades the inside of the dike, the water stop plate that has been standing up to that time falls again to its original state. Therefore, it is easy to draw seawater.

JP-A-8-284139 JP 2007-239233 A JP 2006-241806 A JP 2007-113261 A

  However, in the techniques disclosed in Patent Documents 1 and 2, there is an extremely high risk that sand enters the passage into which seawater flows and closes the passage, and the sand in the passage is always removed. Management is required. Moreover, since these techniques are based on the assumption of a tsunami, pyroclastic flows and earth and sand cannot be blocked. Further, in the techniques disclosed in Patent Documents 3 and 4, since the thing that maintains the standing state of the water blocking plate is the chain or the rope, it is not only extremely vulnerable when a large tsunami occurs. Turbidity and pyroclastic flows cannot be blocked.

  Therefore, the present invention has been proposed for the purpose of solving the problems of the above-mentioned conventional embankment and the like, and utilizes the force of a large-scale fluid generated by a tsunami, muddy flow, pyroclastic flow or other natural phenomenon. While using the levee device which can effectively dam or reduce the force of the large-scale fluid and can be applied to turbulent flow and pyroclastic flow other than tsunami, etc. The purpose is to provide a dike structure.

  The present invention has been proposed in order to solve the above-mentioned problems. The first invention (the invention described in claim 1) includes a base plate fixed to a levee, a road or other construction site, and the base plate. It is arranged on the upper surface and is rotatably connected to the base plate, and a pressure receiving surface is formed on the front surface that receives the pressure of a large-scale fluid generated by a tsunami, muddy flow, pyroclastic flow or other natural phenomenon. A rotating member formed on the rear side with a contact portion that contacts either the base plate or the construction site after the rotation, and the rotating member has a pressure receiving surface that is higher than the pressure receiving surface. When the pressure of the fluid acts on the pressure receiving surface, the height of the rotating member is increased by rotating the rotating member by a predetermined angle. After that Part abuts on either the base plate or a construction site, and is characterized in that to hold the state after the rotation of the pivoting member.

  In the embankment device according to the first invention, first, the base plate is used for construction. This base plate is fixed to a dike, road or other construction site. Other construction sites refer to places where we want to block or reduce the flow of large-scale fluid generated by natural phenomena, and the surroundings of public facilities such as municipal offices, hospitals, schools, etc. Included at the construction site. And the said base plate is fixed to the said construction site, The fixing method is not specifically limited. A rotating member is rotatably connected to the base plate. A pressure receiving surface is formed on the front surface of the rotating member. This pressure receiving surface is a surface that receives a large-scale fluid pressure generated by a natural phenomenon. Further, the rotating member is formed with an abutting portion that contacts the base plate or the construction site after the rotating member rotates on the side opposite to the front surface which is the pressure receiving surface. The rotation position of the rotation member is a connection position between the rotation member and the base plate. For example, when the rotation member and the base member are connected via a connection member such as a hinge, the hinge is configured. The rotating member is configured to rotate around a shaft body (shaft portion) that performs rotation. The distance from the pressure receiving surface to the contact portion is longer than the height of the pressure receiving surface.

  Therefore, a large-scale fluid generated by a natural phenomenon such as a tsunami or a pyroclastic flow hits the pressure receiving surface, and the rotating member rotates a predetermined angle on the base plate, whereby the vertical length (the height of the rotating member). Is extended (becomes high), and then the abutting part abuts on either the base plate or the construction site and holds that state, so that more fluid movement than the state before rotation is blocked or The flow can be reduced.

  According to a second invention (invention of claim 2), in the first invention, an upper plate longer than the height of the pressure receiving surface is disposed on the upper surface of the rotating member, The end is the abutting portion, and the portion where the rotating member rotates is located closer to the pressure receiving surface than the rear end of the upper plate.

  In the second aspect of the invention, an upper plate longer than the pressure receiving surface is disposed on the upper surface of the rotating member, the rear end of the upper plate is used as the contact portion, and the rotating member is Since the rotating part is located closer to the pressure receiving surface than the rear end of the upper plate, when the pressure of the fluid is applied to the pressure receiving surface, the rotating member easily rotates.

  Further, in a third invention (invention according to claim 3), in any one of the first and second inventions, the upper part of the rotating member or the upper part of the upper plate is provided with the rotating member or the upper part. A long plate that is longer than the entire length of the plate is disposed, and the front end of the long plate is rotatably connected to the rotating member or the upper plate, and the rear end side middle portion of the long plate is the lower end. Is pivotally connected at the upper end of a support plate that is pivotally coupled to the base plate, and the rear end of the long plate is at the point when the abutting portion of the pivot member abuts on the base plate. In this case, the contact portion is in contact with the base plate.

  In the dike apparatus according to the third invention, as described above, a large-scale fluid generated by a natural phenomenon such as a tsunami or a pyroclastic flow hits the pressure receiving surface formed on the rotating member, and as a result, the rotating member By rotating a predetermined angle on the base plate, the length in the vertical direction (the height of the rotating member) is extended (becomes high), and then the contact portion formed on the rotating member or the rear end of the upper plate The abutting portion formed on the abutting portion abuts on either the base plate or the construction site, and the abutting portion formed on the rear end of the long plate abuts on the base plate. That is, in the embankment device according to the third invention, the contact portion formed on the rotating member or the contact portion formed on the rear end of the upper plate, and the contact portion formed on the rear end of the long plate Since both of the parts abut against the base plate, the state after the rotation member has been rotated can be held more firmly. And the strength of such a holding state is the length of the long plate, the length of the rotating member or the length of the upper plate (all of these lengths are caused by natural phenomena such as tsunami and pyroclastic flow) The longer the length of the fluid in the moving direction), the more firmly the state after rotation can be maintained.

  According to a fourth invention (invention of claim 4), in the first, second, or third invention, the rotating member is a large-scale fluid generated by a natural phenomenon such as a tsunami or a pyroclastic flow. An inflow space that flows into the inside is formed, and an opening that allows the fluid that has flowed into the inflow space to escape in the same direction as the inflow direction is formed in the rotating member or the upper plate. To do.

  In the fourth aspect of the invention, since the opening that allows the fluid that has flowed into the inflow space to escape in the same direction as the inflow direction is formed in the rotating member or the upper plate, a natural phenomenon such as a tsunami or a pyroclastic flow may occur. The impact of the large-scale fluid generated and the risk of the breakage of the levee device due to this impact can be mitigated.

  According to a fifth invention (invention of claim 5), in any one of the first to fourth inventions, the upper surface of the rotating member, the upper surface of the upper plate, or the upper surface of the long plate is an automobile. It is made into a horizontal surface to such an extent that can travel.

  According to the levee device according to the fifth aspect of the present invention, the levee device group can be used as a road by installing and constructing a number of levee devices arranged in the horizontal direction as in a later-described levee structure.

  According to a sixth invention (invention of claim 7), in the first to fifth inventions, the base plate is formed with a base plate side abutting portion on which the abutting portion abuts. It is a feature.

  According to the levee device according to the sixth aspect of the invention, it is possible to further prevent the rotating device from being destroyed and washed away by a large-scale fluid generated by a natural phenomenon such as a tsunami or a pyroclastic flow.

  A seventh invention (invention according to claim 8) relates to a levee structure using the levee device according to the first to sixth inventions, wherein the levee according to the first to sixth inventions. The apparatus is characterized in that the devices are arranged in the horizontal direction.

  According to the bank structure according to the seventh invention, it is possible to greatly reduce damage caused by a large-scale fluid generated by a natural phenomenon such as a tsunami or a pyroclastic flow.

  An eighth invention (invention according to claim 8) relates to a dike structure using the dike apparatus according to the first to sixth inventions, and relates to the first to sixth inventions. The levee device is installed at a predetermined interval, and the connecting plate is supported on the upper surface of the rotating member, the upper surface of the upper plate, or the upper surface of the long plate constituting the dyke device, and the connecting plate It is characterized by connecting individual dike devices.

  According to the bank structure according to the eighth aspect of the invention, a large-scale fluid generated by a natural phenomenon such as the tsunami or pyroclastic flow hits the pressure receiving surface of the rotating member constituting each bank apparatus, and as a result, When the moving member rotates, the connecting plate serves as a pressure receiving surface and can block the fluid such as the tsunami. Therefore, according to the eighth aspect of the invention, the amount of manufacturing the dike apparatus can be reduced. Further, according to the embankment structure according to the eighth aspect of the present invention, when the tsunami arrives from the sea and seawater returns to the sea again due to tide, the seawater moving in the opposite direction hits the connecting plate and rotates again. The entire state can be restored to the previous state, and if it is restored in this way, the space between the individual levee devices is a space, so that the seawater rushed from the space to the land is prevented from returning to the sea. It will never be.

  According to the embankment apparatus according to the first invention (the invention described in claim 1), the large-scale fluid is effectively used while utilizing the force of the large-scale fluid generated by a tsunami, turbid flow, pyroclastic flow or other natural phenomenon. In addition to being able to reduce damming or its force, it is also possible to apply it to turbid flows and pyroclastic flows other than tsunami.

  In the second invention (the invention described in claim 2), an upper plate longer than the pressure receiving surface is disposed on the upper surface of the rotating member, and the rear end of the upper plate is connected to the contact portion. In addition, since the portion where the rotating member rotates is positioned on the pressure receiving surface side with respect to the rear end of the upper plate, the rotating member is moved when receiving the pressure of the fluid on the pressure receiving surface. It becomes easy to rotate.

  In the embankment device according to the third invention (the invention described in claim 3), the abutting portion formed on the rotating member or the abutting portion formed on the rear end of the upper plate, and the rear of the long plate Since both the abutting portions formed at the ends abut on the base plate, the state after the rotating member rotates can be held more firmly, and the strength of such a holding state is The length of the scale plate is longer than the length of the rotating member or the length of the upper plate (all of these lengths in the moving direction of a large-scale fluid generated by a natural phenomenon such as a tsunami or pyroclastic flow). The longer it is, the stronger the state after rotation can be held.

  In the embankment device according to the fourth invention (invention of claim 4), the turning member or the upper plate is formed with an opening for allowing the fluid flowing into the inflow space to escape in the same direction as the inflow direction. Therefore, the impact of a large-scale fluid generated by a natural phenomenon such as a tsunami or a pyroclastic flow, and the risk of the levee device being destroyed by this impact can be mitigated.

  In the embankment device according to the fifth invention (the invention described in claim 5), the upper surface of the rotating member, the upper surface of the upper plate, or the upper surface of the elongated plate is made to be a horizontal plane so that the automobile can run. Therefore, as in the dyke structure described later, even when levee devices are installed and installed in a horizontal direction or when individual levee devices are connected by connecting plates, the levee device group is used as a road. can do.

  Moreover, in the dike apparatus according to the sixth invention (invention of claim 6), since the base plate is formed with a base plate side abutting portion with which the abutting portion abuts, a further rotating device is provided. It is possible to prevent the danger of being destroyed and washed away by a large-scale fluid generated by a natural phenomenon such as a tsunami or pyroclastic flow.

  Moreover, according to the bank structure concerning 7th invention (invention of Claim 7), it becomes possible to reduce greatly the damage by the large-scale fluid which generate | occur | produces by natural phenomena, such as a tsunami and a pyroclastic flow.

  Moreover, according to the bank structure concerning 8th invention (invention of Claim 8), the large-scale which generate | occur | produces on the pressure receiving surface of the rotation member which comprises each bank apparatus by natural phenomena, such as the said tsunami and a pyroclastic flow. If a fluid hits and the rotating member rotates as a result, the connecting plate becomes a pressure receiving surface, and the fluid such as the tsunami can be blocked. Therefore, according to the eighth aspect of the invention, the amount of manufacturing the dike apparatus can be reduced. Further, according to the embankment structure according to the eighth aspect of the present invention, when the tsunami arrives from the sea and seawater returns to the sea again due to tide, the seawater moving in the opposite direction hits the connecting plate and rotates again. The entire state can be restored to the previous state, and if it is restored in this way, the space between the individual levee devices is a space, so that the seawater rushed from the space to the land is prevented from returning to the sea. It will never be.

It is a right view which shows the embankment apparatus which concerns on 1st Embodiment. It is a perspective view which shows the dike structure which made the dike apparatus shown in FIG. 1 parallel in the width direction. It is a right view which shows the state after the embankment apparatus shown in FIG. 1 rotated. It is a right view which shows the embankment apparatus which concerns on 2nd Embodiment. It is a perspective view which shows the levee structure which made the levee apparatus shown in FIG. 4 parallel in the width direction. It is a right view which shows the state after the embankment apparatus shown in FIG. 4 rotated. It is a perspective view which shows the state after the embankment apparatus shown in FIG. 4 rotated. It is a front view which shows the levee structure which made the levee apparatus shown in FIG. 4 parallel in the width direction. FIG. 5 is a partially exploded perspective view showing another bank structure using the bank apparatus shown in FIG. 4. It is a front view which shows the other dike structure using the dike apparatus shown in FIG. It is a right view which shows the state before the embankment apparatus connected with the connection plate rotates. It is a right view which shows the state after the embankment apparatus connected with the connection plate shown in FIG. 11 rotated.

  Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the drawings. First, a dike apparatus according to the first embodiment and a dike structure using the dike apparatus will be described.

  The embankment device 1 according to this embodiment is for damming or reducing the force of a tsunami as a large-scale fluid generated by a natural phenomenon. As shown in FIG. 1 or FIG. The base plate 2 is fixed to the upper surface of the levee L, and the rotating member 3 is disposed on the upper surface of the base plate 2. As shown in FIG. 2, the base plate 2 is formed into a substantially flat plate shape with concrete, and has a length in the width direction of the existing levee L. Further, a protruding portion 2a protruding upward is formed on the upper surface of the rear side of the base plate 2 (opposite to the sea side). That is, as shown in FIG. 1, the base plate 2 has a flat surface portion 2b on which the rotating member 3 is disposed, and an inclined surface portion 2c that is formed behind the flat surface portion 2b and forms the protruding portion 2a. An upper surface portion 2d that is the upper surface of the protruding portion 2a and a back surface portion 2e that is the back surface of the base plate 2 are provided. In this embodiment, the base plate 2 is fixed to the upper surface of the existing levee L by a plurality of bolts 5 (see FIG. 2) screwed to nuts (not shown) embedded in the levee L. Has been. The protruding portion 2a, the flat surface portion 2b, or the inclined surface portion 2c is a base plate side abutting portion constituting the present invention.

  Moreover, the said rotation member 3 is formed with concrete, and as shown in FIG. 2, it is located in the upper surface of the right-and-left vertical plates 6 and 7 and these right-and-left vertical plates 6 and 7. The upper plate portion 8 is composed of a rear plate 9 that is continuous with the rear ends of the left and right vertical plates 6 and 7 and the rear end of the upper plate portion 8. The front surfaces of the left and right vertical plates 6 and 7 are pressure receiving surfaces 6a and 7a to which a tsunami hits. The back plate 9 is inclined so as to be gradually separated from the pressure receiving surfaces 6a and 7a from the lower end to the upper end side. The inside surrounded by the left and right vertical plates 6 and 7 as the pressure receiving surfaces 6a and 7a, the upper plate portion 8 and the back plate 9 is an inflow space (reference numeral is omitted) into which tsunami flows. is there. In addition, an opening 8a is formed on the rear end side of the upper plate portion 8 to allow a tsunami that has entered the inflow space to escape from the inflow space. Further, the upper surface of the upper plate portion 8 is horizontal, and the width thereof is a width that allows the automobile to travel. And the rotation member 3 comprised in this way is connected on the said baseplate 2 via the hinge 10 so that rotation is possible. In other words, the rotating member 3 is connected to the lower end of the back plate 9 (the lower end on the rear side of the rotating member 3) by a member having a rotating shaft (not shown) as a component, and the rotating shaft It is comprised so that it can rotate in the clockwise direction in FIG. The height of the left and right vertical plates 6 and 7 is shorter than the length of the left and right vertical plates 6 and 7 (depth length) and the length of the upper plate portion 8 (depth length). It is said that. Further, the front end of the upper plate portion 8 protrudes slightly forward from the upper ends of the left and right vertical plates 6 and 7.

  In the embankment device 1 according to the present embodiment, as will be described later, the dike device 1 rotates around a rotation shaft (not shown) that constitutes the hinge 10 until the back surface of the back plate 9 contacts the upper surface of the base plate 2. When the member 3 rotates, the rear end of the upper plate portion 8 and the upper end of the back plate 9 (the upper corner portion on the rear side of the rotating member 3) abut on the protruding portion 2a.

  And as shown in FIG. 2, the bank apparatus 1 which concerns on the structure mentioned above is arrange | positioned in parallel in the width direction of the said upper plate part 8, and this continuous upper plate part 8,8,8 ... The upper surface is a road on which a car (or a bicycle or other vehicle) or a person can travel or pass. That is, FIG. 2 shows a levee structure using the levee device 1, and the upper plate portion 8 of each rotating member 3 maintains a horizontal state in a normal state. And in such a state, the tsunami caused by the occurrence of the earthquake hits the pressure receiving surfaces 6a, 7a (and the front surface of the upper plate portion 8) which are the front surfaces of the rotating members 3, 3, 3. When the tsunami flows into the rotating member 3 and comes into contact with the front surface of the back plate 9, each rotating member 3 rotates on the base plate 2 and forms the hinge 10 on the base plate 2 as shown in FIG. 3. 1 is rotated in the clockwise direction in FIG. 1, and the rear surface of the back plate 9 eventually comes into contact with the upper surface 2b of the base plate 2, and the rear end of the upper plate portion 8 is an inclined surface portion constituting the protruding portion 2a ( 2c) is restricted from rotating further. And if the rotation member 3 rotates in this way and will be in the state shown in FIG. 3, it will be in a state higher than the height of the rotation member 3 until then, and it can dam a tsunami or reduce the power. A part of the tsunami (seawater) that flows into the inflow spaces inside the left and right vertical plates 6 and 7 escapes to the outside of the rotating member 3 from the opening 8a. The rotating member 3 is prevented from falling off the base plate 2 or the rotating member 3 itself being destroyed.

  Next, a dike structure according to the second embodiment and using this dike apparatus will be described. As shown in FIG. 4 or FIG. 5, the dike apparatus 21 according to the second embodiment includes a base plate 22, a rotating member 23, a long plate 24, and a support plate 25.

  In the case of this embodiment, the base plate 22 is also fixed on the existing levee L, and a protruding portion 22a protruding upward from a horizontal upper surface 22b is formed on the rear side. Moreover, the said rotation member 23 consists of the structure similar to the rotation member 3 which concerns on the said 1st Embodiment. That is, the rotating member 23 is also composed of left and right vertical plates 26 and 27, an upper plate 28, and a back plate 29. The front surfaces of the left and right plates 26 and 27 are pressure receiving members that constitute the present invention. Surfaces 26a and 27a. The upper plate 28 constituting the rotating member 23 is also provided with an opening 28a for allowing a tsunami that has entered the inflow space formed inside the rotating member 23 to escape from the inflow space to the outside. ing. And the lower end of the back plate 29 which comprises the said rotation member 23, and the base plate 22 are connected with the 1st hinge 30 so that rotation is possible.

  The front end of the long plate 24 is connected to the front side of the upper plate 28 constituting the rotating member 23 via a second hinge 31. As shown in FIGS. 4 and 5, the long plate 24 is formed to be longer than the entire length (depth length) of the upper plate 28, and the width thereof is the upper plate 28. The same dimension as the width of

  The middle part of the rear end side of the long plate 24 is supported by the support plate 25. The support plate 25 and the long plate 24 are rotatably connected to each other via a third hinge 32, and the lower end of the support plate 25 and the base plate 22 are connected by a fourth hinge 33. The support plate 25 is rotatably connected to the base plate 22. The support plate 25 is erected in a substantially vertical direction, and the width thereof is formed to be the same as the width of the long plate 24.

  Hereinafter, a dike structure using the dike apparatus 21 according to the above-described embodiment will be described. As shown in FIGS. 5 and 8, the levee structure described first is one in which the levee devices 21 are arranged in the width direction. According to such a levee structure, since the upper surface of the levee structure is covered with the long plate 24 arranged horizontally, an automobile or other vehicle can travel in the width direction of the long plate 24. 5 and 8, a large-scale fluid pressure generated by a natural phenomenon such as a tsunami (not shown) acts on the front surfaces of the vertical plate portions 26 and 27 which are the pressure receiving surfaces 26a and 27a. At the same time, when seawater flows into the rotating member 23, the entire rotating member 23 rotates in the clockwise direction in FIG. 4 around the first hinge 30 (the axis constituting the first hinge 30). The long plate 24 rotates around a second hinge 31 (a shaft constituting the long hinge 31) so that an angle is formed between the long plate 24 and the upper plate 28 constituting the rotating member 23. It rotates about the fourth hinges 32 and 33 (each axis constituting them). In this case, the support plate 25 also rotates in the clockwise direction in the same manner as the rotation member 23. Then, the rear end of the long plate 24 rotated together with the rotating member 23 is, as shown in FIGS. 6 and 7, a protrusion 22a formed on the rear end side of the base plate 22 or the inclined surface portion described above. It abuts on 22c, and that state is maintained and maintained. In this way, when the state shown in FIGS. 6 and 7 is reached, the height of the rotating member 23 is considerably higher than the height when maintaining the horizontal state until then, so that the tsunami is blocked. Or the force can be reduced. In particular, in the levee device 21 according to this embodiment, as shown in FIG. 6, the rotation of the rotating member 23 causes the rear end of the upper plate 28 and the back plate 29 constituting the rotating member 23 to be attached to the base plate 22. This is a case where a considerable force acts on the levee device 21 because it abuts the upper surface 22b and the rear end of the long plate 24 abuts the protrusion 22a at the rear position of the rotating member 23. However, it can withstand that force and prevent the danger of being destroyed.

  Next, a bank structure according to another example using the bank apparatus 21 will be described. As shown in FIGS. 9 and 10, in this levee structure, a plurality of the dyke devices 21 are arranged with a predetermined distance apart in the width direction, and the dyke device 21 and the dyke device 21 are arranged on the dyke device 21. The connecting plates 38, 38, which are longer than the distance between them, are mounted and fixed. In this example, the connecting plate 38 has a width substantially the same as the length of the long plate 24.

  Even in such a structure, when the rotating member 23 is rotated by a tsunami or the like from the state shown in FIG. 11, the connecting plates 38 and 38 are simultaneously rotated as shown in FIG. The later state is maintained.

  In particular, as described above, the embankment structure in which the embankment device 21 is installed separately and connected by the connecting plate 38 can reduce the number of the embankment devices 21, thereby reducing the cost. When the state shown in FIG. 12 is reached, the connecting plate 38 can block a tsunami or the like or reduce its force. Further, in the dike structure using the dike device 21, when the seawater returns to the sea after the tsunami hits, the rotating member 23 returns to the original state again due to the movement pressure of the seawater against the upper surface of the connecting plate 38. To do. And when the rotation member 23 returns to the original state in this way, as shown in FIG. 10, since the space between the embankment device 21 and the embankment device 21 is vacant, the movement of the seawater is hindered. Never come.

  In each of the above embodiments, the function and effect of each embankment device 1, 21 and the embankment structure using them has been described on the assumption that a tsunami has occurred. However, in the vicinity of mountain ridges and public facilities It may be installed or constructed for the purpose of blocking or reducing the force of earth and sand, muddy flow or pyroclastic flow.

1 (according to the first embodiment) 2 Base plate 2a Protruding portion 3 Rotating member 6 Left vertical plate 6a Pressure receiving surface 7 Right vertical plate 7a Pressure receiving surface 8 Upper plate 8a Opening 9 Back plate 10 Hinge 21 ( Embankment device 22 Base plate 22a Protruding portion 23 Rotating member 24 Long plate 26 Left vertical plate 26a Pressure receiving surface 27 Right vertical plate 27a Pressure receiving surface 28 Upper plate 28a Opening 29 Back plate 30 1 hinge 31 2nd hinge 32 3rd hinge 33 4th hinge 38 Connecting plate L Existing levee

Claims (8)

A base plate fixed to a construction site such as a dike, road,
Located on the upper surface of the base plate and connected to the base plate so as to be rotatable, a pressure receiving surface is formed on the front surface to receive a large-scale fluid pressure generated by a tsunami, muddy flow, pyroclastic flow or other natural phenomenon. A rotating member formed on the back side with a contact portion that contacts either the base plate or the construction site after rotation,
The rotating member has a longer length from the pressure receiving surface to the contact portion than the height of the pressure receiving surface, and when the fluid pressure acts on the pressure receiving surface, the rotating member is predetermined. The height of the rotating member is increased by rotating at an angle, and then the contact portion contacts either the base plate or the construction site, and maintains the rotated state of the rotating member. Embankment equipment to do.   An upper plate longer than the pressure-receiving surface is disposed on the upper surface of the rotating member, and the rear end of the upper plate is used as the abutting portion. The embankment device according to claim 1, wherein the embankment device is located closer to the pressure receiving surface than the rear end of the upper plate.   A long plate that is longer than the entire length of the rotating member or the upper plate is disposed above the rotating member or the upper plate, and the front end of the long plate is the rotating member or the upper plate. The middle part of the rear end side of the long plate is rotatably connected to the upper end of a support plate that is rotatably connected to the base plate, and the long plate 3. The levee according to claim 1, wherein the rear end is a contact portion that contacts the base plate when the contact portion of the rotating member contacts the base plate. 4. apparatus.   The rotating member is formed with an inflow space into which a large-scale fluid generated by a natural phenomenon such as a tsunami or a pyroclastic flow flows, and the rotating member or the upper plate is provided in the inflow space. 4. An embankment device according to any one of claims 1, 2 and 3, wherein an opening is formed to allow the fluid that has flowed in to escape in the same direction as the inflow direction.   The upper surface of the rotating member, the upper surface of the upper plate, or the upper surface of the long plate is a horizontal surface to the extent that an automobile can run. Embankment equipment.   6. The dike apparatus according to claim 1, wherein a base plate side abutting portion with which the abutting portion abuts is formed on the base plate.   An embankment structure comprising the embankment devices according to claim 1 arranged in parallel in a lateral direction.   The levee device according to any one of claims 1 to 6 is installed at a predetermined interval and is connected to an upper surface of a rotating member, an upper surface of an upper plate, or an upper surface of a long plate constituting the levee device. An embankment structure in which individual embankment devices are connected by the connecting plate.