JP5209140B1 - Flood evacuation room - Google Patents

Abstract

The present invention provides a flood evacuation room that can evacuate safely and reliably for several hours without moving over a long distance in the event of a flood such as a tsunami, storm surge, or flood.
A flood damage evacuation room 2 installed underground, an evacuation space 20 having an outer wall 28, an inner wall 32 fixed to the outer wall 28, a floor portion 16 and a ceiling 34 that can be raised and lowered, and an underfloor space 18, the float 30 for floating the floor 16 by floating with the water stored in the underfloor space 18, the entry stairs 6 from the ground to the evacuation space 20, and the entry stairs 6 and the evacuation space 20 communicate with each other. It comprises an opening 14 and a hatch 26 for escaping to the ground. When water flows into the flood evacuation chamber 2, water enters the underfloor space 18 and is floated to the height of the upper end of the opening 14 by the float 30. The upper surface of the part 16 rises, and is composed of a flood evacuation room in which an air space is secured by the raised floor part 16, the inner wall 32, and the ceiling 34.
[Selection] Figure 2

Description

  The present invention relates to a flood evacuation room when a flood such as a tsunami, storm surge, or flood occurs.

  In the Great East Japan Earthquake that occurred on March 11, 2011, many people on the coast were unable to evacuate to high ground and were swept away by the tsunami and sacrificed. From this situation, it has become difficult in many cases to live on the coast. However, there are not a few cases where it is not possible to move to high ground, and there are many cases where it is necessary to be in the coastal area, such as when working in a fishery facility. In addition to tsunamis, there is a need for an environment where people living and working in lowlands can live and work with peace of mind even if storm surges or floods occur due to typhoons.

  Non-Patent Document 1 discloses evacuation to an egg-shaped floating capsule when a tsunami comes and flows. However, it is highly possible that the capsule will collide with other floating objects while being flowed, resulting in a large impact.

  Patent Document 1 discloses a tsunami shelter that is installed on the ground. “A structure in which the evacuation chamber 3 is made into an air pocket by raising the floor 12 inside the evacuation chamber 3 from the lowest ceiling 15 of the communication passage ceiling of the entrance 2. [0011] "is disclosed. Because this tsunami shelter is installed on the ground, there is a high possibility that it will be destroyed or washed away by the strong water flow of the tsunami.

  There are many evacuation rooms installed in the basement, including Patent Document 2, but if water enters the evacuation space in the basement and immerses the entire evacuation room, it is often unusable. To prevent this, If steel hatches are installed at the doorway, a heavy hatch will have to be opened and closed when evacuating.

Homepage address: http://commonpost.boo.jp/?p=14784

Patent Publication No. 4822087 Registered Utility Model Publication No. 3033727

  The present invention has been made in view of such circumstances, and provides a flood evacuation room that can evacuate safely and reliably for several hours without moving over long distances in the event of a flood such as a tsunami, storm surge, or flood The purpose is to do. In this application, “water damage” is defined by the concept including tsunami, storm surge, and flood.

  In order to achieve the above object, the present invention is a flood evacuation room installed in the basement, and includes an accommodation wall, a side part accommodated in the accommodation wall and fixed to the accommodation wall, and a floor part that can be raised and lowered And an evacuation space having a ceiling portion, an underfloor space provided under the floor portion, a float means for floating the floor portion by floating with water stored in the underfloor space, and provided in the accommodation wall, When water flows into the flood evacuation room, consisting of an approach path from the ground to the evacuation space, an opening that connects the access path and the evacuation space, and an escape means for escaping from the evacuation space to the ground A flood damage evacuation room in which an air space is secured by the floor and side portions, and the ceiling, where water has entered into the underfloor space and the upper surface of the floor has risen to the height of the upper end of the opening by the float means, Consists of.

  According to the present invention, in the event of a flood caused by a tsunami or flood, when the water flows on the ground, the water also flows onto the flood evacuation chamber and flows into the flood evacuation chamber from the approach path. The inflowing water immerses upward from the bottom of the flood evacuation chamber in order. That is, water permeates into the underfloor space from the opening, but the float means floats by the water stored in the underfloor space to float the floor, and the upper surface of the floor rises to the height of the upper end of the opening. However, after that height, water does not enter the evacuation space due to Pascal's principle. Therefore, the inside of the evacuation space is not immersed in water, and an air space is secured by the raised floor portion, side surface portion, and ceiling portion. In the evacuation space, the floor portion rises to the above-described position and has an air space sealed inside, so that buoyancy works. However, the side surface portion of the evacuation space is fixed to the accommodation wall and thus does not rise. For example, a person can stay in the air space for a certain period of time (for example, several hours) until at least tsunami water is drawn. When the water on the ground is pulled, escape to the ground by the escape means.

  As a procedure for evacuating to the flood evacuation room, people get down the approach path from the ground when they obtain information that a tsunami or flood is likely to attack. The approach path may be a slope or stairs. Then, it passes through the opening from the approach path, moves to the floor, and arrives at the evacuation space. By adopting the float means, the lower end of the approach path and the floor of the floor can be made the same height. It is good to store food and water for several hours in the evacuation space.

  Because the flood evacuation room is installed underground, it is hardly swept away by water flowing on the ground such as tsunami and flood. This can be recognized from the fact that the foundation of the building remained even after the tsunami hit during the Great East Japan Earthquake that occurred on March 11, 2011.

  The present invention can have a pressure reducing means for reducing the atmospheric pressure in the evacuation space.

  According to this, the pressure in the evacuation space can be reduced by the decompression means, and the floor can be raised. If the floor is raised, the height at which a person stands will be closer to the ceiling.

  In the present invention, the escape means may be an openable / closable outlet provided on a side surface portion of the evacuation space and leading to the approach path.

  According to this, the escape means is provided on the side surface portion of the evacuation space and is an openable / closable outlet that leads to the access path, so that a person in the evacuation space opens the side surface outlet and passes through the exit path. Can go out to the ground. That is, a person can go out to the ground without climbing to the ceiling. In addition, in order to be able to open the exit of a side part, it is the conditions that it is not flooded to the height which can open an exit.

  In the present invention, the escape means may further comprise an openable and closable exit provided at the ceiling of the evacuation space, and the exit may communicate with the ground.

  According to this, a person opens the exit part provided in the ceiling part and goes out to the ground. This exit part corresponds to, for example, an evacuation hatch.

  According to the present invention, it is possible to provide a stopper for limiting the rise of the floor in the evacuation space.

  This stopper can prevent the floor from rising and reaching the ceiling.

  In the present invention, it is possible that a visual recognition means capable of visually recognizing the ground environment is attached to the ceiling outer wall of the flood evacuation room.

  By this visual recognition means, the ground environment can be visually confirmed. For example, it can be confirmed whether or not water on the ground has been drawn, and it can be determined whether or not to escape to the ground.

  The present invention is a flood evacuation room installed in the basement, and includes an accommodation wall, an evacuation space that is accommodated in the accommodation wall and is fixed to the accommodation wall, a floor portion, and a ceiling portion. An entrance path from the ground to the evacuation space, an opening formed in the entrance path, and an entrance for a person to enter the evacuation space; and an entrance path, which closes the opening. A water-damaged water comprising a closing member capable of rotating between an open state and a closed state, a float portion attached to the closed member, and an escape means for escape from the evacuation space to the ground. When the air flows into the evacuation room, the floating member is floated by the water that has flowed in, so that the closing member rotates to the closed state, and further includes a flood evacuation room that prevents the water from flowing into the entrance path.

  According to the present invention, when water damage occurs and water enters the evacuation space from the approach path, the floating member is floated by the inflowing water, so that the closing member to which the float is attached rotates to the closed state. . The blocking member prevents further inflow of water into the approach path.

  In the present invention, a plurality of approach paths can be provided.

  In the present invention, the approach path is provided at a position adjacent to the evacuation space, and the closing member can block the opening of the approach path to the evacuation space. That is, the closing member can turn to close the opening of the approach path to the evacuation space, and can prevent water from flowing into the evacuation space.

  In the present invention, the approach path is provided at the entrance to the flood evacuation room, and the closing member can block the opening of the entry path to the flood evacuation room. That is, the closing member can close the opening portion of the approach path by rotating, and can prevent further inflow of water into the approach path.

  In the present invention, it can be assumed that a storage space for storing water stored in the approach path is provided below the evacuation space, and a valve mechanism for flowing the stored water to the storage space is provided. By opening the valve mechanism, the water stored in the approach path can be stored in the storage space.

  According to the present invention, ventilation means having a ventilation outlet in contact with outside air is provided in the evacuation space, and the ventilation outlet is configured to be occluded by a floating material accommodated in the accommodation path, and the accommodation path is on the flood evacuation room. Therefore, it can be assumed that it is provided at a position where water can flow in during a flood. During normal times, the evacuation space is hermetically sealed, so we want to ventilate it with ventilation means. If water flows into the flood evacuation room during a flood, the water also flows into the containment chamber, the floating material contained in the containment chamber floats and the floater closes the ventilation outlet, and the water from the ventilation exit to the evacuation space Inflow is blocked.

  In the present invention, a solar panel is installed on the flood evacuation room, and the ventilation means can be operated by the electric power generated by the solar panel. Since the ventilation means is operated by the electric power generated by the solar panel, the inside of the evacuation space is ventilated on a daily basis without requiring another power source.

  According to the present invention, since the flood evacuation room can be installed in the basement of a home garden or in a public space, in the event of a tsunami or flood, evacuate safely and reliably instantly without going to a distant hill. be able to. In particular, for example, there is a very high possibility of evacuation in a short time from when a tsunami warning is issued until the first tsunami wave arrives. This is especially effective for people who live in plains where there are no hills or who work in coastal facilities such as fisheries.

Overview cross-sectional view of the flood evacuation room of the present invention installed in the basement of the garden of a house The perspective view of the state which has a floor part in the lowest position in the flood refuge room of 1st Embodiment of this invention AA line sectional view of FIG. The perspective view of the state where the floor rose in the flood refuge room of the first embodiment of the present invention BB sectional view of FIG. The perspective view which showed the flood refuge room of 2nd Embodiment of this invention 6A is a plan view of the flood evacuation chamber of the embodiment of FIG. 6 with the ceiling removed, FIG. 6B is a cross-sectional view taken along the line CC in FIG. 6, and FIG. 6C is a cross-sectional view taken along the line DD in FIG. The perspective view which showed the flood refuge room of 3rd Embodiment of this invention

  Hereinafter, a first embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present embodiment, an example will be described in which a person is temporarily evacuated to a flood evacuation room when a tsunami is likely to strike and escapes from the flood evacuation room when water from the tsunami is pulled.

  FIG. 1 is a schematic cross-sectional view of the flood evacuation chamber 2 according to the present invention installed in the basement of a house garden.

  As shown in the figure, a flood damage evacuation room 2 can be installed in the basement of a house garden. When installing, first dig the basement into a rectangular parallelepiped. The bottom and periphery of the dug rectangular parallelepiped are hardened with the outer wall 28. The outer wall 28 is generally made of concrete. An evacuation chamber unit body 3 to be described later is installed inside the outer wall 28. Furthermore, the outer wall 28 is also attached to the upper part of the rectangular parallelepiped, that is, the part that hits the upper lid.

  A fence 42 is installed on the ground portion of the entrance 4 entering the evacuation room unit 3 so as to surround the entrance 4 so that the presence of the entrance 4 can be seen from the ground. The entrance 4 is not attached with a lid but is an opening. This is because there seems to be no time or mental allowance to lift or open a heavy lid during an emergency evacuation. An entrance door 40 is formed at one end of the fence 42 and is attached to the fence 42 so that it can be opened and closed. A roof 46 is attached to cover the entrance 4 to prevent rain. In case of emergency evacuation, it is possible to evacuate from the entrance 4 to the evacuation space 20 in the flood evacuation room 2 simply by opening the entrance door 40.

  A hatch 26, a pressure reducing valve 36, and a camera 38 are attached to the upper cover of the outer wall 28. The hatch 26 has a function as an exit when exiting from the flood evacuation chamber 2 to the ground. The pressure reducing valve 36 is a pressure reducing means for reducing the pressure in the evacuation space 20 in the flood evacuation chamber 2, and a pressure gauge (not shown) is attached to check the pressure value in the evacuation space 20. The camera 38 projects the environment on the ground, and serves as a means for confirming the state of the ground, for example, whether tsunami water has been drawn when a person is retreating to the evacuation space 20.

  The structure of the flood damage evacuation chamber 2 will be described in detail with reference to FIGS. FIG. 2 is a perspective view showing the flood evacuation chamber 2 with the floor 16 in the lowest position. FIG. 4 is a perspective view showing the flood evacuation chamber 2 in a state where the floor portion 16 is raised.

  In the flood evacuation chamber 2, the evacuation chamber unit body 3 is installed in a rectangular parallelepiped space surrounded by the outer wall 28 described above. The evacuation room unit body 3 is mainly divided into a part for forming the evacuation space 20 and a part for reaching the evacuation space 20.

  The part for reaching the evacuation space 20 includes an entrance 4, an approach staircase 6, a landing 8, and an entrance 12.

  The entrance 4 is a square opening. An entrance staircase 6 extends downward from directly under the entrance 4 and further down in the opposite direction via the landing 8 on the way. An entrance 12 composed of a rectangular flat floor is formed at the lower end of the approach stairs 6.

  An evacuation space 20 is formed adjacent to the entrance 12. The evacuation space 20 has a rectangular parallelepiped shape, and includes a floor portion 16 constituting a bottom surface, an inner wall 32 constituting a side surface, and a ceiling 34 constituting an upper surface. The floor 16, the inner wall 32, and the ceiling 34 are made of fiber reinforced plastic (FRP). A rectangular opening 14 is formed at the center in the width direction of the substantially lower half of the inner wall 32 on the side surface adjacent to the entrance 12. The opening 14 is formed up to the bottom of the inner wall 32 on the side surface. The opening 14 is sized to allow a person to pass. The floor 16 is made of plywood. A float 30 is attached to the entire back surface of the floor 16. An underfloor space 18 can be formed under the float 30. The floor 16 has a structure in which when the water enters the underfloor space 18, the float 30 floats on the water and the floor 16 rises. When water is drawn, the floor 16 is lowered. As the material of the float 30, a polystyrene foam, a polypropylene foam, an olefin plastic foam or the like can be applied. An appropriate thickness of the float is 5 to 15 cm.

  When the floor 16 is in the lowest position, the surface of the floor 16 and the surface of the entrance 12 are at the same height, but there is a gap at the position of the opening 14 between the floor 16 and the entrance 12. Is formed. Water enters through this gap and enters the underfloor space 18.

  Columnar stoppers 22 are erected on the four corners of the floor 16. This is to prevent the evacuation space 20 from disappearing due to the floor 16 coming into contact with the ceiling 34 when the floor 16 is raised.

  A ladder 24 is attached to the upper part of the inner wall 32. A hatch 26 is attached to the ceiling 34 above the ladder 24. You can escape by climbing the ladder 24 and opening the hatch 26. The hatch 26 can be made of steel, for example.

  A side door 10 is attached to a portion of the inner wall 32 corresponding to the landing 8. The side door 10 can be opened to the landing 8 side. When the floor 16 is at the highest position, the floor 16 and the landing 8 are at substantially the same height, and when the floor 16 is in the position, the water does not reach the height of the landing 8 of the entrance stairs 6 The side door 10 can be opened. The side door 10 is a waterproof door.

  A pressure reducing valve 36 is attached to the ceiling 34. The pressure reducing valve 36 is a screw type, and when it is turned, the air in the evacuation space 20 comes out and the atmospheric pressure in the evacuation space decreases.

  The camera 38 attached to the upper lid of the outer wall 28 has a monitor 44 attached to the ceiling 34 and has a structure that generates power when wet.

  The operation of the present embodiment will be described using a tsunami as an example.

  Upon receiving information that a tsunami is coming, evacuees go to the garden with the minimum necessary amount. Open the entrance door 40, enter the flood evacuation room 2 from the entrance 4, and go down the entrance stairs 6. Enter the entrance 12, pass through the opening 14, and enter the floor 16 of the evacuation space 20. Since the entrance 12 and the floor portion 16 are almost the same height, they are easy to move because they are difficult to pinch in the event of an emergency. The approach staircase 6 may be composed of a slope for a wheelchair, and the entrance 12 and the floor 16 are substantially the same height, and therefore can be easily moved by a wheelchair.

  It is assumed that a tsunami hits while waiting on the floor 16 of the evacuation space 20. Water flows into the garden of the house and destroys the fence 42, and water flows into the flood evacuation room 2 from the entrance 4. The water that has flowed down the entrance stairs 6 vigorously. Since the side door 10 of the landing 8 is closed at this time, water does not enter the evacuation space 20 from the side door 10. The water descending the entrance stairs 6 reaches the entrance 12, enters the gap between the entrance 12 and the floor 16, and enters the underfloor space 18 from the lower part of the opening 14. When even a small amount of water enters the underfloor space 18, the float 30 rises, so that the water flowing from the opening 14 does not enter the floor 16.

  The float 30 is lifted by the water successively entering the underfloor space 18 and the floor 16 is raised. When the float 30 floats up to the height of the upper end of the opening 14, no matter how much water flows into the flood evacuation chamber 2 from the entrance 4, the float 30 does not flow into the evacuation space 20. It doesn't rise above. Accordingly, the floor 16 does not rise any further. FIG. 4 shows this position. This is due to the Pascal principle. Therefore, the evacuation space 20 is maintained as an air space, and a person can wait for a certain amount of time (for example, several hours) until the tsunami water is drawn. In the evacuation space 20, buoyancy works because the floor portion 16 rises to the above-described position and has an air space sealed inside, but the inner wall 32 of the evacuation space 20 is fixed to the outer wall 28 by anchor bolts. Does not surface.

  While in the evacuation space 20, the refugee looks at the monitor 44 of the camera 38 to see if water on the ground has drawn. When it is confirmed that the water on the ground has been drawn, the evacuees rotate the pressure reducing valve 36 in the pressure reducing direction to reduce the atmospheric pressure in the evacuation space 20. As the pressure is reduced, the float 30 rises and the floor 16 rises. The rise of the floor portion 16 stops when the stopper 22 abuts against the ceiling 34. At that time, the decompression valve 36 is rotated in the non-decompression direction so that water does not enter the evacuation space 20. The pressure reducing valve 36 is operated while checking the atmospheric pressure value in the evacuation space 20 with the pressure gauge.

  At the position where the stopper 22 is in contact with the ceiling 34, the floor 16 and the lower end of the side door 10 are almost at the same height, so that there is no water outside the side door 10 and the side door 10 faces outward. If it opens, it will go out to the landing 8 from the side door 10, and will go up the entrance stairs 6 and escape to the ground.

  When water is sprayed outside the side door 10 and the side door 10 does not open outward, the ladder 24 is raised, the hatch 26 is opened, and the ground door 10 comes out.

  According to the present embodiment, it is possible to evacuate safely for several hours until a tsunami is pulled under the garden of the house without moving a long distance up to a hill. The evacuation space 20 may be provided with food, drinks, portable toilets, etc. for several hours. It is advisable to bring or install a mobile phone equipped with a GPS (Global Positioning System) function or an emergency position indicating radio beacon device in the evacuation space 20. This is to make it easier to receive rescues from others during evacuation.

  The installation of the flood evacuation room 2 is not limited to a home garden, but may be under a park, a kindergarten garden, a public hall, a public space, or the like. The scale of the evacuation room unit body 3 can be increased or decreased depending on the installation location and the number of persons to be accommodated. The flood evacuation room 2 is desired to be maintained once a year.

  In the present embodiment, the outer wall 28 and the evacuation space 20 have a rectangular parallelepiped shape, but these can also be a cylindrical shape. By setting it as a cylindrical shape, the pressure from the surrounding earth wall and the pressure from the water with which the circumference | surroundings of the evacuation space 20 were filled can be received equally.

  A second embodiment of the present invention will be described with reference to FIGS.

  FIG. 6 is a perspective view showing a flood damage evacuation chamber 52 according to the second embodiment of the present invention. The same structures and members as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  The flood evacuation room 52 is installed in the basement of the home garden, like the flood evacuation room 2 of the first embodiment. The flood evacuation chamber 52 is provided with an inner staircase 58 without using a float.

  The flood evacuation chamber 52 is provided with an evacuation chamber unit 53 in a rectangular parallelepiped space surrounded by the outer wall 28. The evacuation chamber unit body 53 is mainly divided into a part for forming the evacuation space 64 and a part for reaching the evacuation space 64.

  The part for reaching the evacuation space 64 is composed of the entrance 4, the entrance stairs 66 and the exit 54. An entrance staircase 66 extends downward from the entrance 4, but there is no landing. When going down the entrance stairs 66, a landing 54 consisting of a flat space is provided.

  An evacuation space 64 is formed adjacent to the entrance stairs 66 and the landing 54. An inner wall 32 is formed between the entry stairs 66, the landing 54 and the evacuation space 64. The evacuation space 64 has a box-like shape, and an entrance space 62 adjacent to the landing 54 through a hollow 56 that opens the inner wall 32 in a rectangular shape, an inner staircase 58 continuous from the entrance space 62, and a floor surface that continues from the inner staircase 58. 60, an inner wall 32, and a ceiling 34. The floor surface 60, the inner wall 32, and the ceiling 34 are made of fiber reinforced plastic (FRP). The height of the bore 56 is desirably 50 cm to 1 m lower than the height of the floor 60, and is 70 cm lower in this embodiment. The approach stairs 66 and the inner stairs 58 may be slopes.

  The operation of the second embodiment will be described by taking a tsunami as an example.

  Upon receiving information that a tsunami is coming, evacuees go to the garden with the minimum necessary amount. Open the entrance door 40, enter the flood evacuation room 52 from the entrance 4, and go down the entrance stairs 66. Get off at the landing 54, pass through the entrance 56 and enter the entrance space 62, climb the inner stairs 58 and enter the floor 60 of the evacuation space 64.

  It is assumed that a tsunami hits while waiting on the floor surface 60 of the evacuation space 64. The water flow comes to the garden at home and destroys the fence 42, and water flows into the flood evacuation room 52 from the entrance 4. The water that has flowed down the entry stairs 66 vigorously. The water that has gone down the entrance stairs 66 reaches the landing 54 and enters the entrance space 62 through the opening 56. The water that has entered the entrance space 62 gradually increases in volume and rises up the inner stairs 58. That is, water enters the evacuation space 64.

  The water rises so as to rise up the inner staircase 58. However, the height of the bore 56 is 70 cm lower than the height of the floor 60, so that the water level above the upper end of the bore 56 is due to Pascal's principle. Do not enter the evacuation space 64. Therefore, the evacuation space 64 is maintained as an air space, and a person can wait for a certain amount of time (for example, several hours) until the tsunami water is drawn. Although the evacuation space 64 has an air space sealed inside, buoyancy works. However, since the inner wall 32 of the evacuation space 64 is fixed to the outer wall 28 by anchor bolts, it does not rise.

  While in the evacuation space 64, the refugee looks at the monitor 44 of the camera 38 to see if water on the ground has drawn. When it is confirmed that the water on the ground has been drawn, the ladder 24 is raised, the hatch 26 is opened, and the ground is exited.

  According to the present embodiment, it is possible to evacuate safely for several hours until a tsunami is pulled under the garden of the house without moving a long distance up to a hill. The evacuation space 64 may be provided with food, drinks, portable toilets, etc. for several hours. In the evacuation space 64, it is preferable to bring or install a mobile phone equipped with a GPS (Global Positioning System) function or an emergency position indicating radio beacon device. This is to make it easier to receive rescues from others during evacuation.

  Installation of the flood evacuation room 52 is not limited to the garden at home, but may be under a park, a kindergarten garden, a public hall, a public space, or the like. The scale of the evacuation room unit 53 can be increased or decreased according to the installation location and the number of persons to be accommodated. It is desirable to maintain the flood evacuation room 52 about once a year.

  In the second embodiment, the outer wall 28 and the evacuation space 64 are box-shaped, but they may be cylindrical. By setting it as a cylindrical shape, the pressure from the surrounding earth wall and the pressure from the water with which the circumference | surroundings of the evacuation space 64 were filled can be received equally.

  A third embodiment of the present invention will be described with reference to FIG.

  FIG. 8 is a perspective view showing a flood damage evacuation chamber 98 according to the third embodiment of the present invention. The same structures and members as those of the second embodiment are denoted by the same reference numerals and description thereof is omitted.

  The flood damage evacuation room 98 is installed in the basement of the home garden, like the flood damage evacuation room 52 of the second embodiment. The flood evacuation chamber 98 is provided with a slope 81 without using a float.

  The flood evacuation chamber 98 is provided with an evacuation chamber unit 53 and a storage space 68 in a rectangular parallelepiped space surrounded by the outer wall 28. The evacuation room unit body 53 is mainly divided into a part for forming the evacuation space 102 and a part for reaching the evacuation space 102.

  A portion for reaching the evacuation space 102 includes an entrance 4, a slope 78, a landing 54, an entrance space 62, and a slope 81. A slope 78 extends downward from the entrance 4, and a rectangular closing plate 72 that allows the entrance 4 to be closed is attached to a base end portion of the slope 78 by a hinge 76. . A float plate 74 is in close contact with the back surface of the closing plate 72.

  An evacuation space 102 is formed adjacent to the slope 78 and the landing site 54. An inner wall 32 is formed between the slope 78, the landing 54 and the evacuation space 102. The evacuation space 102 has a box shape. Up to the evacuation space 102, an entrance space 62 adjacent to the landing area 54 and a slope 81 continuous from the entrance space 62 are formed through a hollow 56 opening the inner wall 32 in a rectangular shape. The evacuation space 102 includes a floor surface 60, an inner wall 32, and a ceiling 34 that continue from the slope 81. The height of the bore 56 is desirably 50 cm to 1 m lower than the height of the floor 60, and is 70 cm lower in this embodiment. Above the slope 81, an ascending opening 100 is formed by hollowing out the floor surface 60. The slope 81 is composed of a rectangular closing plate 80, and a hinge 84 is attached to the tip of the closing plate 80, and is configured to be rotatable about the hinge 84, so that the rising port 100 can be closed. A float body 82 is in close contact with the back surface of the closing plate 80.

  Under the evacuation space 102, a storage space 68 for storing the inflowing water is formed. A valve mechanism 70 for dropping inflowing water into the storage space 68 is attached to the inlet space 62.

  A ventilation fan 88 is attached to the upper corner of the evacuation space 102. A ventilation cylinder 90 is connected to the ventilation fan 88, and a ventilation outlet 86 at the end of the ventilation cylinder 90 projects into a rectangular parallelepiped hole 94 that is cut out from the outside to the evacuation space side. The ventilation outlet 86 has an outlet bent downward by 90 degrees with respect to the ventilation fan 88, and a floating member 92 is disposed directly below the outlet. A solar panel 96 is installed on the upper cover of the outer wall 28, and the ventilation fan 88 is operated by the electric power generated here.

  The operation of the third embodiment will be described by taking a tsunami as an example.

  Upon receiving information that a tsunami is coming, evacuees go to the garden with the minimum necessary amount. Open the entrance door 40, enter the flood evacuation room 98 from the entrance 4, and go down the slope 78. Get off at the landing 54, pass through the entrance 56 and enter the entrance space 62, climb the slope 81 and enter the floor 60 of the evacuation space 102.

  It is assumed that a tsunami hits while waiting on the floor surface 60 of the evacuation space 102. The water flow comes to the garden at home and destroys the fence 42, and water flows into the flood evacuation room 98 from the entrance 4. The water that has flowed down the slope 78 vigorously. The water descending the slope 78 reaches the landing 54 and enters the entrance space 62 through the opening 56. The water that has entered the entrance space 62 gradually increases in volume and rises up the slope 81. That is, water enters the evacuation space 102.

  The water level rises so as to rise up the slope 81, but the height of the bore 56 is 70 cm lower than the height of the floor surface 60. Therefore, due to Pascal's principle, the water level above the upper end of the bore 56 is evacuated. It does not enter the space 102. Therefore, the evacuation space 102 is maintained as an air space, and a person can wait for a certain amount of time (for example, several hours) until the tsunami water is drawn. Buoyancy works because the evacuation space 102 has an air space sealed inside, but the inner wall 32 of the evacuation space 102 is fixed to the outer wall 28 by anchor bolts, so it does not rise.

  Further, as water accumulates in the entrance space 62, the closing plate 80 gradually rotates upward with the hinge 84 as a base axis due to the buoyancy of the float body 82 in close contact with the back surface.

  Before the water reaches the level of the opening 56, the closing plate 80 is rotated to the horizontal position by the buoyancy of the float body 82 and closes the rising port 100. Therefore, even if water further enters the flood evacuation chamber 98 from the entrance 4, the evacuation space 102 has a structure in which water does not enter due to the dual means of the Pascal principle and the rotation of the slope 81. .

  When water further fills the slope 78 in the approach path, the closing plate 72 is now rotated upward with the hinge 76 as a base axis due to the buoyancy of the float plate 74 in close contact with the back surface. When the slope 78 is completely filled with water, the closing plate 72 rotates to the horizontal position and closes the entrance 4. As a result, water does not enter the flood evacuation chamber 98 any more.

  While in the evacuation space 102, the refugee looks at the monitor 44 of the camera 38 to see if water on the ground has drawn. When it is confirmed that the water on the ground has been drawn, the ladder 24 is raised, the hatch 26 is opened, and the ground is exited.

  According to the present embodiment, it is possible to evacuate safely for several hours until a tsunami is pulled under the garden of the house without moving a long distance up to a hill. The evacuation space 102 may be provided with food, drinks, portable toilets, etc. for several hours. In the evacuation space 102, a mobile phone equipped with a GPS (Global Positioning System) function or an emergency position indicating radio beacon device may be brought in or installed. This is to make it easier to receive rescues from others during evacuation.

  The installation of the flood evacuation room 98 is not limited to the garden at home, but may be under a park, a kindergarten garden, a public space, or the like. The scale of the evacuation room unit 53 can be increased or decreased according to the installation location and the number of persons to be accommodated. The flood evacuation room 98 is desired to be maintained once a year. Further, when not in use (normal time), it is desirable to ventilate the evacuation space 102, and the ventilation fan 88 may be operated by the electric power generated by the solar panel 96. In the ventilation outlet 86 of the ventilation fan 88, when water enters the pit hole 94 in the event of a flood, the floating material 92 floats by buoyancy and closes the ventilation outlet 86, so that water does not enter the ventilation cylinder 90 from the ventilation outlet 86. The float 92 can be a polystyrene foam ball or the like.

  In order to drain the water in the passage (entrance path) to the evacuation space 102 including the slope 78, the landing 54, the entrance space 62, and the slope 81, the valve of the valve mechanism 70 is opened to store the water 68. To drop. The water dropped in the storage space 68 is pumped up separately.

  In the third embodiment, the outer wall 28 and the evacuation space 102 are box-shaped, but they may be cylindrical. By adopting the cylindrical shape, pressure from surrounding soil walls and pressure from water filled around the evacuation space 102 can be equally received.

  2 ... Flood evacuation room, 3 ... Evacuation room unit body, 4 ... Entrance, 6 ... Entrance stairs, 10 ... Side door, 12 ... Entrance, 14 ... Opening, 16 ... Floor, 18 ... Under floor space, 20 ... Evacuation Space, 22 ... Stopper, 24 ... Ladder, 26 ... Hatch, 28 ... Outer wall, 30 ... Float, 32 ... Inner wall, 34 ... Ceiling, 36 ... Decompression valve, 38 ... Camera, 44 ... Monitor, 52 ... Water evacuation room, 53 ... Evacuation room unit, 54 ... Get-off, 56 ... Groundhole, 58 ... Inner staircase, 60 ... Floor surface, 62 ... Inlet space, 64 ... Evacuation space, 66 ... Entry staircase, 68 ... Reservation space, 70 ... Valve mechanism 72 ... Closure plate, 74 ... Float plate, 76 ... Hinge, 78 ... Slope, 80 ... Obstruction plate, 81 ... Slope, 82 ... Float body, 84 ... Hinge, 86 ... Ventilation outlet, 88 ... Ventilation fan, 92 ... Floating material , 94 ... Hot hole, 96 ... So Paneru, 98 ... flood evacuation chamber, 100 ... Agariguchi, 102 ... evacuation space

Claims (13)

A flood evacuation room installed in the basement,
A containment wall;
An evacuation space having a side part accommodated in the accommodation wall and fixed to the accommodation wall, a floor part capable of moving up and down, and a ceiling part;
An underfloor space provided under the floor,
Float means for floating the floor by floating with water stored in the underfloor space;
An entrance path from the ground to the evacuation space provided in the housing wall;
An opening communicating the approach path and the evacuation space;
And escape means for escaping from the evacuation space to the ground,
When water flows into the flood evacuation room, water enters the underfloor space, the float means raises the upper surface of the floor to the height of the upper end of the opening, and the raised floor and the side surface, And a flood evacuation room in which an air space is secured with the ceiling.   The flood evacuation chamber according to claim 1, further comprising pressure reducing means for reducing the atmospheric pressure in the evacuation space.   The flood evacuation chamber according to any one of claims 1 to 2, wherein the escape means includes an openable / closable outlet provided on a side surface of the evacuation space and leading to the approach path.   The flood evacuation chamber according to any one of claims 1 to 3, wherein the escape means further comprises an openable and closable exit provided at a ceiling of the evacuation space, and the exit communicates with the ground. .   The flood evacuation chamber according to any one of claims 1 to 4, wherein a stopper is provided in the evacuation space to limit the rise of the floor.   The flood evacuation chamber according to any one of claims 1 to 5, wherein visual recognition means capable of visually recognizing the ground environment is attached to an outer wall of the ceiling of the flood evacuation chamber. A flood evacuation room installed in the basement,
A containment wall;
An evacuation space having a side part, a floor part, and a ceiling part accommodated in the accommodation wall and fixed to the accommodation wall;
An entrance path from the ground to the evacuation space provided in the housing wall;
An opening formed in the approach path for a person to enter the evacuation space;
A closing member provided in the approach path, capable of closing the opening and being rotatable between an open state and a closed state;
A float attached to the closure member;
And escape means for escaping from the evacuation space to the ground,
A flood evacuation chamber in which when the water flows into the flood evacuation chamber, the floating member floats due to the inflowed water, so that the closing member rotates to the closed state and prevents further water from flowing into the entrance path .   The flood evacuation chamber according to claim 7, wherein a plurality of the approach paths are provided.   The flood evacuation chamber according to claim 7 or 8, wherein the approach path is provided at a position adjacent to the evacuation space, and the blocking member is capable of closing an opening of the approach path to the evacuation space.   9. The flood evacuation chamber according to claim 7, wherein the approach passage is provided at an entrance to the flood evacuation chamber, and the blocking member can close an opening portion of the entry passage to the flood evacuation chamber.   11. A storage space for storing water stored in the approach path is provided below the evacuation space, and a valve mechanism for flowing the stored water into the storage space is provided. The flood evacuation room described in item 1.   The evacuation space is provided with ventilation means having a ventilation outlet in contact with the outside air, and the ventilation outlet is configured to be closed by a floating material accommodated in the accommodation passage, and the accommodation passage is on the flood evacuation chamber. The flood evacuation chamber according to any one of claims 7 to 11, which is provided at a position where water can flow in during a flood.   The flood evacuation chamber according to claim 12, wherein a solar panel is installed on the flood evacuation chamber, and the ventilation means is operated by electric power generated by the solar panel.

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