JP5373951B2 - Evacuation float - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an evacuation float 1 which has a floating body floating up on the occurrence of a tsunami, which reliably protects an evacuee 50, which achieves rapid floatation of the floating body 2, and the large number of which can be installed by becoming widespread. <P>SOLUTION: An evacuation float has a floating body floating up on the occurrence of a tsunami. The evacuation float 1 comprises the floating body 2, and an ocean-side slope 4 which is formed toward a top surface of the floating body 2 from a ground surface 3 on the ocean side of the floating body 2. The ocean-side slope 4 has a through-hole 11 through which seawater passes. <P>COPYRIGHT: (C)2013,JPO&amp;INPIT

Description

  The present invention relates to an evacuation float having a floating body that floats when a tsunami occurs.

  As countermeasures for tsunamis, there is an evacuation float that is normally installed on land and floats when it reaches the tsunami (see, for example, Patent Document 1). FIG. 8 shows an example of this evacuation float. FIG. 8A shows a normal evacuation float 1X, and FIG. 8B shows an evacuation float 1X when a tsunami arrives. This evacuation float 1X has a plurality of mooring piles 13X driven deep into the ground, and a float 2X movable in the vertical direction along the mooring piles 13X. When a tsunami warning or the like is issued, the refugee 50 uses the stairs 51 to evacuate on the float 2X. The float 2X is configured to lift off the ground surface 3 by buoyancy when a tsunami arrives.

  With this configuration, the following operational effects can be obtained. First, since the float 2X floats when it reaches the tsunami, for example, even if a tsunami that reaches 5m from the ground surface 3 occurs, the float 2X floats 5m and protects the refugee 50 (See FIG. 8B). Second, the float 2X is installed on the ground surface 3 and is located close to the ground surface 3, so that evacuation is easy (see FIG. 8A). In other words, as long as the staircase 51 provided to the float 2X goes up, damage can be avoided even if the tsunami reaches the second or third floor of the building.

  However, the evacuation float 1X has several problems. 1stly, the float 2X will be destroyed at the time of tsunami arrival, and it has the problem that the refugee 50 cannot fully be protected. This is because the float 2X installed on the ground surface 3 receives the horizontal force of the tsunami on its side surface. In addition, there is a high possibility that drifting objects (fishing boats, automobiles, houses, etc.) carried by the tsunami collide with the float 2X and destroy the float 2X.

  Second, even if the evacuees 50 evacuate on the float 2X, there is a problem that they may be involved in a tsunami. This is because when a tsunami occurs, the tsunami may pass above the float 2X before the float 2X sufficiently rises. Here, for example, fishing boats that have encountered a tsunami offshore can move in the vertical direction as the tide level changes, so there is little damage. However, when the tsunami reaches the float 2X installed on the ground surface 3, the float 2X may be subjected to the tsunami soon before rising. Therefore, it is not enough as an actual evacuation site.

  Third, there is a problem that it is difficult to secure a place for installing the evacuation float 1X. This is because there are many things with higher priority than the installation of the evacuation float 1X in consideration of land use during normal times.

  As described above, the conventional evacuation float 1X has a possibility that the refugee 50 cannot be sufficiently protected when a tsunami occurs and has a difficulty in spreading.

JP 2006-112089 A

  The present invention has been made in view of the above problems, and its purpose is to reliably protect the evacuees in the evacuation float having a floating body that floats when a tsunami occurs, and to realize rapid floating of the floating body, It is also to provide an evacuation float that can be widely installed and installed.

  The evacuation float according to the present invention for achieving the above object is an evacuation float having a floating body that floats when a tsunami occurs, wherein the evacuation float is on the sea side of the floating body and the floating body from the ground surface. It has the sea side slope formed toward the upper surface of the said floating body, The said sea side slope has a through-hole which lets seawater pass, It is characterized by the above-mentioned.

  With this configuration, it is possible to prevent an accident in which the floating body is destroyed by a tsunami or drifting material. This is because the sea-side slope having the through hole weakens the wave force and prevents the passage of drifting objects. In addition, a place for installing the evacuation float can be easily secured. This is because a vehicle or the like can travel on the floating body by installing the sea-side slope.

  In the above evacuation float, the evacuation float is formed at a position lower than the surrounding ground surface, the floating body disposed in the basin, and the sea surface from the sea surface of the evacuation float. It has the water channel which guides seawater toward.

  With this configuration, since the time when sufficient buoyancy is generated in the floating body is advanced, the evacuees can be protected more safely. In addition, since the height of the upper surface of the floating body is reduced, the evacuation float can be easily installed on a road or a parking lot.

  The evacuation float according to the present invention for achieving the above object is an evacuation float having a floating body that floats when a tsunami occurs, and the evacuation float is formed at a position lower than the surrounding ground surface; The floating body arranged in the tank, a water intake part formed at a position lower than the surrounding ground surface on the sea side of the evacuation float, and a water channel connecting the tank and the water intake part. It is characterized by that. With this configuration, buoyancy can be obtained at an early stage of tsunami generation, so that refugees can be protected more safely. In addition, a place for installing the evacuation float can be easily secured.

  In the above evacuation float, the floating bodies are containers connected to each other by a connecting hardware. With this configuration, the construction period can be significantly shortened and the construction cost can be significantly reduced.

  According to the evacuation float according to the present invention, it is possible to provide a evacuation float that realizes quick floating of the floating body, reliably protects the refugee, and can be widely installed.

It is the schematic which showed the side of the float for evacuation of embodiment which concerns on this invention. It is the schematic of the float for evacuation of embodiment which concerns on this invention. It is the schematic of the float for evacuation of embodiment which concerns on this invention. It is the schematic which showed the side of the float for evacuation of different embodiment which concerns on this invention. It is the schematic of the float for evacuation of embodiment which concerns on this invention. It is the schematic of the float for evacuation of embodiment which concerns on this invention. It is the schematic which showed the floating body of the float for evacuation of embodiment which concerns on this invention. It is the schematic which showed the side of the conventional evacuation float.

  Hereinafter, an evacuation float according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows a side surface of an evacuation float 1 according to an embodiment of the present invention. FIG. 1A (upper stage) shows a normal evacuation float 1, and FIG. 1B (lower stage) shows an evacuation float 1 when a tsunami occurs. The evacuation float 1 has a floating body 2, an inclined sea-side slope 4 extending from the ground surface 3 to the upper surface of the floating body 2, and legs 12 installed at the lower part of the floating body 2. Further, the slope 5 may be installed on the land side of the floating body 2.

  The sea-side slope 4 has a through hole 11 through which seawater of the tsunami W passes. Moreover, the sea side slope 4 is comprised so that passage of the drifting material etc. which are shed by the tsunami W can be prevented. Specifically, punching metal, grating (iron lattice), or the like can be used.

  This floating body 2 can be comprised similarly to the material which comprises a conventional floating pier, such as a steel plate and concrete. The size of the floating body 2 is assumed to be, for example, about 30000 mm to 60000 mm in vertical length in a plan view, about 60000 mm to 90000 mm in horizontal length, and about 2000 mm to 5000 mm in height (thickness). Moreover, the length of the seaside slope 4 in the sea direction is assumed to be about 20000 mm to 50000 mm in plan view. Furthermore, the leg 12 assumes a height of about 500 to 800 mm.

  In addition, the white arrow has shown the direction of the tsunami W, and the arrow has shown the image of the flow of seawater. In FIG. 1, the right side is the sea side and the left side is the land side.

  Next, the operation of the evacuation float 1 will be described. First, after a tsunami warning or the like is issued, the evacuees go up the slopes 4 and 5 on foot or by the vehicle 40 and move on the floating body 2. When the tsunami W arrives, the seawater passes through the through-hole 11 of the sea-side slope 4 and flows below the floating body 2 (see FIG. 1A). As the water level rises (water surface 6), the floating body 2 gains buoyancy and rises (see FIG. 1B). Here, although it is assumed that the legs 12 are fixed to the floating body 2 side, the legs 12 may be fixed to the ground surface 3 side.

  With the above configuration, the following operational effects can be obtained. First, destruction of the floating body 2 due to the tsunami W can be prevented, and the evacuees can be protected safely. This is because the sea-side slope 4 having the through-hole 11 brings about the same effect as the wave-dissipating block that reduces the horizontal impact of the tsunami W. Moreover, this sea side slope 4 is because it can prevent the accident which drifts, such as debris, a motor vehicle, and a house collide with the floating body 2. FIG.

  Secondly, the floating body 2 can rise quickly with the arrival of the tsunami W and can safely protect the evacuees. This is because the seawater is easily moved below the floating body 2 by the legs 12 installed on the lower surface of the floating body 2.

  Thirdly, a place for installing the evacuation float 1 can be easily secured. This is because the evacuation float 1 has the floating body 2 on which the vehicle 40 and the like can travel on the upper surface. That is, since the vehicle 40 can move on the evacuation float 1, the evacuation float 1 can be installed in the middle of a road or as a parking lot of a commercial facility. Moreover, the evacuation float 1 can also be installed as a part of a bridge or a part of an overpass.

  The floating body 2 is preferably a rectangular parallelepiped pontoon type. With this configuration, manufacturing becomes easy and the work period can be shortened. In addition, the floating body 2 may be constructed as a single unit, but preferably a block construction in which a plurality of blocks are constructed and assembled at the place where the evacuation float 1 is installed. With this configuration, the construction period can be shortened and the work cost can be reduced.

  FIG. 2 shows an example of the evacuation float 1. The evacuation float 1 includes a floating body 2, a sea-side slope 4 having a plurality of through holes 11, a land-side slope 5, a mooring pile 13 and a mooring roller 14 for mooring the floating body 2. The floating body 2 has legs 12 on the lower surface.

  As shown in FIG. 2, the floating body 2 is configured to be moored by a chain or a mooring pile with respect to the ground surface 3 so as not to be swept horizontally by the tsunami W, similarly to the structure for mooring a floating pier or the like. desirable. In particular, when moored by the mooring pile 13, since the horizontal movement of the floating body 2 hardly occurs, the floating body 2 can return to the original position after the seawater is drawn. That is, recovery work after the tsunami is easy or unnecessary. In addition, when the water level becomes higher than expected, a release mechanism for releasing the mooring by the mooring pile 13 or the chain of the floating body 2 may be installed. Specifically, for example, when the floating body 2 rises beyond the height of the mooring pile 13, the floating body 2 can be configured to be detached from the mooring pile 13. Further, when a certain force or more is applied to the chain for mooring, the releasing mechanism constituted by a shear pin or the like is opened, and the mooring of the floating body 2 can be released.

  Moreover, you may install the jack up and jack down function in the leg 12. FIG. With this configuration, the inclination of the floating body 2 can be adjusted even when the floating body 2 is inclined due to ground subsidence or the like.

  Furthermore, it is good also as a structure which installs the fin which rectifies seawater in the lower surface of the sea side slope 4 or the floating body 2, and the inside of the through-hole 11. FIG. For example, the fins can be installed so as to be suspended vertically from the seaside slope 4 or the lower surface of the floating body 2 such that the direction from the sea side toward the floating body 2 is the longitudinal direction. With this configuration, it is possible to prevent a situation in which the seawater vortexes on the seaside slope 4 and the lower surface of the floating body 2 and the floating body 2 cannot quickly obtain buoyancy.

  In addition, a skirt 16 may be installed on the lower side surface of the floating body 2 so as to surround the floating body 2 (see FIG. 3). The skirt 16 is installed to prevent debris or the like from entering between the floating body 2 and the ground surface 3. The skirt 16 is preferably formed in a bellows shape using, for example, a metal, resin, or rubber net. Further, the skirt 16 is configured such that the lower end does not separate from the ground surface 3 when the floating body 2 floats (see FIG. 3B).

  With this configuration, the flow of the ocean current on the lower surface of the floating body 2 can be rectified in the same manner as the above fins. Moreover, since debris and the like can be prevented from entering below the floating body 2, the restoration work is facilitated. In particular, as shown in FIG. 2, it is desirable to install the skirt 16 on the side surface of the floating body 2 where the slopes 4 and 5 are not installed. Even on the side surface of the floating body 2 on which the slopes 4 and 5 are installed, the skirt 16 can be installed.

  FIG. 4 shows a side view of an evacuation float 1a according to another embodiment of the present invention. FIG. 4A (upper stage) shows a normal evacuation float 1a, and FIG. 4B (lower stage) shows an evacuation float 1a when a tsunami occurs. This evacuation float 1a is formed from a tank 20 formed by a ground surface 3a dug down to a position lower than the surrounding ground surface 3, a floating body 2 installed in the tank 20, and a ground surface 3 on the sea side to the tank 20 It has an inclined channel 21 that guides seawater toward it.

  Next, the operation of the evacuation float 1a will be described. First, when the tsunami W reaches the evacuation float 1a, the seawater is preferentially guided to the water channel 21 and moves into the tank 20 (see FIG. 4A). At the same time, seawater that has passed through the through-hole 11 (not shown) of the sea-side slope 4 also flows into the tank 20. Compared with the surrounding ground surface 3, the water level from the ground surface 3a in the tank 20 rises quickly, and the floating body 2 floats (see FIG. 4B).

  With the above configuration, the following operational effects can be obtained. First, since sufficient buoyancy occurs in the floating body 2 earlier, it is possible to protect the evacuees more safely.

  Secondly, since the height of the upper surface of the floating body 2 with respect to the ground surface 3 is reduced, the slopes 4 and 5 can be made shorter, and the slopes of the slopes 4 and 5 can be formed gently. Therefore, the evacuation float 1a can be easily installed on a road or a parking lot.

  The upper surface of the floating body 2 may be at a position higher than the surrounding ground surface 3 or the same height as the ground surface 3. When the upper surface of the floating body 2 is set to the same height as the surrounding ground surface 3, the degree of freedom of the place where the evacuation float 1a is installed is dramatically improved.

  FIG. 5 shows an example of the evacuation float 1a. The evacuation float 1 a includes a floating body 2, a sea-side slope 4, a plurality of slopes 5 installed at positions other than the sea side of the floating body 2, and a water channel 21 that guides seawater from the ground surface into the tank 20 (not shown). Have.

  Here, only the sea side slope 4 is made into the slope which has the through-hole 11, and the other direction is comprised with the members which do not have water permeability, such as concrete. With this configuration, seawater can be actively retained on the lower surface of the floating body 2, and the time when the floating body 2 rises can be advanced. In addition, it is good also as a structure which installs the 2 or more sea side slope 4 in the float 1a for evacuation. When seawater may flow from two or more directions, the time when the floating body 2 rises can be advanced.

  FIG. 6 shows a schematic diagram of an evacuation float 1b according to another embodiment of the present invention. The evacuation float 1b has a tank 20 formed to be lower than the ground surface 3, a floating body 2 arranged in the tank 20, the sea side of the floating body 2, and a position lower than the ground surface 3. It has the water intake part 22 formed, and a water channel 21 b that connects the water intake part 22 and the tank 20. The water intake unit 22 has a water intake plate 23 formed on the upper surface by grating or the like. The intake plate 23 only needs to have a configuration that allows seawater to pass therethrough as in the case of the above-described seaside slope 4 but does not allow drifting material or the like to pass therethrough.

  The floating body 2 has upper structures such as a building 41, a storage 42, and a parking lot 43. Furthermore, the floating body 2 has a flap 15 that covers a groove between the floating body 2 and the ground surface 3 and facilitates passage of a vehicle or the like.

  Next, the operation of the evacuation float 1b will be described. First, when the tsunami reaches the intake section 22, seawater flows into the intake section 22. The seawater reaches the tank 20 while increasing the moving speed in the water channel 21b. The floating body 2 starts levitation by obtaining buoyancy from the seawater filled in the tank 20.

  With the above configuration, the following operational effects can be obtained. First, since the floating body 2 can obtain buoyancy at an early stage of tsunami generation, it is possible to protect the evacuees more safely. This is because the seawater moving through the water channel 21b has a higher speed than the tsunami moving through the ground surface 3. Therefore, it is desirable to form the water intake unit 22 in a place close to the sea.

  Second, it is possible to easily secure a place for installing the evacuation float 1b. This is because the building 41 of the evacuation float 1b can be used normally. Specifically, for example, the building 41 can be a public institution such as a city hall, a library, and a children's house. The storage 42 is preferably formed of a prefabricated material and stores articles such as emergency food and blankets.

In addition, the waterway 21b suppresses the construction that is newly required when using the sewerage, etc.
An evacuation float 1b can be installed. Moreover, you may comprise so that the tank 20 may be previously filled with seawater or a fluid with high viscosity (saturated sodium chloride solution etc.). With this configuration, the floating body 2 can obtain buoyancy at an earlier time when the tsunami occurs. In addition, the configuration of filling the fluid with high viscosity prevents the fluid from flowing out of the tank 20 even when cracks or the like are generated in the tank 20 due to the influence of an earthquake, etc. Can surface.

  In FIG. 7, the schematic of the floating body 2c of different embodiment of this invention is shown. FIG. 7A shows the floating body 2c under construction, and FIG. 7B shows the floating body 2c that has been built. The floating body 2c includes a container 30 that has been subjected to watertight processing in advance, a connection hardware 31 that connects the containers 30 (for example, a connection hardware called a twist lock or a stacking cone), and a connection plate 32. This container 30 is a container for marine transportation, for example, a 20 ft container or a 40 ft container.

  Next, the construction method of the floating body 2c will be described. First, the opening / closing door of the container 30 is closed and watertight processing is performed. The containers 30 are fixed to each other with a twist lock 31 while being stacked in the vertical direction. Here, the twist lock 31 is a hardware that is inserted into and fixed to a through-hole formed in the container 30, and connects the containers 30 to each other in the vertical direction. Further, a connecting plate 32 is installed between the containers 30 arranged in the horizontal direction, and fixed with a twist lock 31. The connecting plate 32 can be formed of a steel plate or the like, and is used for connecting containers 30 arranged in the horizontal direction. Then, the block connected to the size which can be conveyed on land is conveyed to the installation place of the evacuation float 1. In this installation place, a plurality of blocks are connected by a twist lock 31 and a connecting plate 32. The floating body 2c configured by the container 30 is constructed through the above steps (see FIG. 7B).

  With this configuration, the floating body 2c can be constructed using a standard product called the container 30, so that the construction period can be greatly shortened and the construction cost can be significantly reduced.

DESCRIPTION OF SYMBOLS 1 Float for evacuation 2 Floating body 3 Ground surface 4 Sea side slope 11 Through-hole 12 Leg 20 Tank 21, 21b Water channel 22 Water intake part 30 Container 31 Connection hardware (twist lock)

Claims (4)

In an evacuation float with a floating body that floats when a tsunami occurs,
The evacuation float has a floating body and a sea-side slope formed on the sea side of the floating body from the ground surface toward the upper surface of the floating body,
The seaside slope has a through-hole through which seawater passes , and is arranged so as to cover the entire seaside side surface of the floating body .   A tank formed in a position where the evacuation float is lower than the surrounding ground surface, the floating body arranged in the tank, and a water channel for guiding seawater from the sea-side ground surface of the evacuation float toward the tank. The evacuation float according to claim 1, characterized by comprising: The evacuation float according to claim 1 or 2, wherein the evacuation float has a skirt installed so as to surround the floating body from a lower side surface of the floating body. The evacuation float has a floating body that floats when a tsunami occurs, and the evacuation float has a floating body and a sea-side slope formed on the sea side of the floating body from the ground surface toward the upper surface of the floating body. The sea-side slope has a through-hole through which seawater passes, and is a method for manufacturing a floating body of an evacuation float that is arranged so as to cover the entire sea-side surface of the floating body,
  Applying watertight processing to the container;
  A step of installing a twist lock in a through-hole of the container to connect the container in a vertical direction, and disposing a connecting plate between the containers arranged in a horizontal direction and fixing the twist plate with the twist lock; A manufacturing method of a floating body.

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