JP4838395B1 - Structure - Google Patents

Abstract

An object of the present invention is to provide a structure capable of returning to the same life as before a tsunami when a resident has returned from an evacuation site without being swept away even if a tsunami comes.
In order to improve tsunami resistance, a structure comprising a foundation part constructed on a site and a living part fixedly connected to the foundation part,
The living part includes a watertight structure that prevents opening of water from the opening to the living part and includes an openable / closable opening used for communication inside and outside the living part,
The weight of the foundation is such that the gravity acting on the structure is larger than the buoyancy acting on the structure in a submerged state.
[Selection] Figure 1

Description

  The present invention relates to a tsunami countermeasure technique for a structure.

  In the above technical field, as shown in Patent Document 1, a house having a tsunami evacuation shelter is known. This tsunami evacuation shelter can be normally used as a part of a house and has a simple equipment configuration.

JP 2007-277998 A

  However, in a house equipped with the above-mentioned shelter, when a tsunami hits, even if the object in the shelter can be protected, the object in the house that is not put in the shelter cannot be protected. In particular, even after seeing the reports of the Great East Japan Earthquake, the victims have a strong desire to “return to their homes” and not only simply evacuate and protect the lives of the victims, but also protect the living spaces of the victims. Is strongly demanded.

  The objective of this invention is providing the technique which solves the above-mentioned subject.

In order to achieve the above object, the structure according to the present invention is:
A structure comprising a foundation part and a living part fixedly attached to the foundation part,
The living part includes a watertight structure that prevents opening of water from the opening to the living part and includes an openable / closable opening used for communication inside and outside the living part,
Said base portion, than the buoyancy acting on the structure of the submerged state, have a weight such as gravity acting on the structure is increased,
The opening of the living part includes a door body that opens and closes the opening,
The watertight structure provided in the opening includes an elevating body disposed outside the opening,
The lifting body can be raised and lowered to a closed position that covers the door body from the outside, and an open position where the door body is exposed to the outside world,
The elevating body in the closed position is characterized in that a gap region, which is a space between the elevating body and the door body, is watertight with respect to the outside.
It is preferable that the elevating body has a specific gravity lighter than that of water and moves up and down according to the water level outside the living part.
It is preferable that the upper portion of the base portion includes an overhanging portion that extends toward the outside of the bottom area of the living portion.
The outer wall of the living part has a short outer wall part that protrudes outward in two positions, a first position that should receive a tsunami wave and a second position that should receive a pulling wave. It is preferable that the two short outer wall portions are connected by two long outer wall portions.
It is preferable that the outer periphery of the horizontal section of the short outer wall part is an arc having a central angle of 90 degrees or more and 180 degrees or less.
It is preferable that the opening is formed only in the longitudinal outer wall.

  ADVANTAGE OF THE INVENTION According to this invention, even if a tsunami comes, a structure which can be returned to the same life as before the tsunami came when a resident returns from an evacuation place without being pushed away can be provided.

It is a perspective view which shows the detached house which is 1st Embodiment of this invention. It is a front view which shows the house of FIG. It is sectional drawing which shows the housing structure of the cross section seen from the front direction. It is sectional drawing which shows the housing structure of the BB horizontal cross section of FIG. It is a front view which shows the shutter unit of the house of 1st Embodiment. It is sectional drawing which shows the shutter unit frame structure of CC vertical cross section of FIG. 5A. It is a front view which shows the guide roller arrangement | positioning of the shutter unit in the DD vertical cross section of FIG. 5B. It is sectional drawing which shows the guide roller arrangement | positioning of the shutter unit in the EE vertical cross section of FIG. 6A. It is sectional drawing which shows the guide roller arrangement | positioning of the shutter unit in the FF vertical cross section of FIG. 6A. FIG. 6 is a cross-sectional view showing a structure of a cross section orthogonal to the extending direction of the packing used in the shutter unit of FIG. 5. It is sectional drawing which shows the state which the packing of FIG. 8A is contacting the raising / lowering board. It is sectional drawing which shows the structural example of another packing. It is explanatory drawing which shows operation | movement of the shutter unit of the house of 1st Embodiment. It is sectional drawing which shows the structure of the shutter unit installed in the outer side of the window of a house. It is explanatory drawing which shows the state where the house received the tsunami and was submerged. It is a top view for demonstrating the other example of the shape of the residence part of a house. It is a front view for demonstrating the other example of the shape of the residence part of a house. It is explanatory drawing for demonstrating a housing structure provided with the foundation part of 2nd Embodiment. It is explanatory drawing for demonstrating a housing structure provided with the foundation part of 3rd Embodiment. It is explanatory drawing for demonstrating a housing structure provided with the base part of 4th Embodiment. It is explanatory drawing for demonstrating the housing structure provided with the foundation part of 5th Embodiment. It is explanatory drawing for demonstrating a housing structure provided with the foundation part of 6th Embodiment. It is explanatory drawing for demonstrating a housing structure provided with the foundation part of 7th Embodiment.

  Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the drawings. However, the components described in the following embodiments are merely examples, and are not intended to limit the technical scope of the present invention only to them.

(First embodiment)
Next, a single-family house as a first embodiment of the structure according to the present invention will be described with reference to FIGS.

  FIG. 1 is a perspective view of a housing 100 according to the present embodiment as viewed from above. As shown in FIG. 1, the house 100 is integrally provided with a base portion 101 constructed on a site and a living portion 102 fixedly attached to the base portion 101. The base portion 101 is configured to be buried in the ground. The living part 102 includes two short outer wall parts 121 and 122 that receive pressure from a tsunami (push wave and pulling wave), two planar long outer wall parts 123 and 124 that connect the two short outer wall parts, The structure includes a roof 125. Since the direction in which the tsunami comes (basically the coastline direction) is known in advance, the house 100 is constructed such that the two short outer wall portions 121 and 122 are oriented in the tsunami direction. As a result, it is possible to minimize the drag acting on the house 100 when the tsunami is approached, and to avoid damage caused by collapse or flow.

  FIG. 2 is a front view of the house 100 as seen from the longitudinal outer wall 123 side. The base portion 101 includes a cloth base portion 201, an anchor portion 202, and a collar portion 203. The fabric base 201 is a structure with an inverted T-shaped cross section installed for connection with the living part 102, and is continuous with the outer peripheral part of the living part 102 and the lower part of the internal bearing wall and main partition walls. Is provided. The anchor portion 202 is a portion that is configured integrally with the fabric base portion 201 and serves as a weight that is firmly fixed to the ground. On the other hand, the brim part 203 is provided on the outer periphery of the upper surface of the anchor part 202, and is provided in order to exert a tension so that the entire house 100 does not fall over even if it receives the force of pushing waves and pulling waves.

  The cloth foundation part 201, the anchor part 202, and the collar part 203 are all reinforced concrete, and are integrally formed by an integral placing method. In addition, the reinforced concrete of this embodiment is laid by the integral laying method unless otherwise specified.

  The anchor part 202 has a function as a weight of a house and is basically installed in the ground. The heel part 203 has a size that spreads outside the exclusive area of the living part 102. The exclusive area corresponds to the bottom area of the living part 102 when viewed in plan.

  The collar portion 203 has a function of improving the stability of the house 100 and is provided on the outer periphery of the upper end of the anchor portion 202. Therefore, in the house 100, the anchor portion 202 and the flange portion 203 that spread outward from the living portion 102 are the protruding portions of the base portion 101.

  FIG. 3 is a cross-sectional view illustrating a residential structure with a vertical cross section when the house 100 is viewed from the front direction (longitudinal outer wall portion 123 side). As shown in FIG. 3, the fabric foundation 201 is a portion protruding upward from the anchor portion 202, and is the outer wall of the living portion 102 (short outer wall portions 121 and 122 and long outer wall portions 123 and 124). It is the base part. The outer wall and the fabric base portion 201 are firmly connected and integrally configured.

  The living part 102 includes an intermediate part 301 in addition to the outer walls (short outer wall parts 121 and 122 and long outer wall parts 123 and 124) and the roof 125. The intermediate part 301 is a structure that supports the ceiling of the first floor of the house and the floor part of the second floor of the house. The outer wall, the roof 125, and the intermediate portion 301 are all reinforced concrete and are integrally formed.

  Moreover, the short outer wall parts 121 and 122 have a shape constituted by a vertical part S1 extending vertically and a curved corner part S2 formed at the upper end of the vertical part S1. If the upper ends of the short outer wall parts 121 and 122 are rounded toward the outside, the drag acting on the house 100 can be reduced when a large tsunami that causes the entire house to submerge. it can. If the drag acting on the house 100 during the tsunami can be suppressed, the house can be prevented from being destroyed or pushed away.

  It is preferable that the corner portion S2 which is a connecting portion between the roof 125 and the outer wall further includes a reinforcing member. An example of the reinforcing member is a steel plate. And it is preferable that the reinforcement member is connected with the reinforcement which is one of the structural materials of the reinforced concrete which comprises the roof 125 and an outer wall, and it is more preferable that it is integral. Furthermore, examples of the arrangement of the reinforcing member include an arrangement in which the reinforcing member is exposed on the outer surface of the corner and an arrangement in which the reinforcing member is embedded in the reinforced concrete constituting the roof 125 and the outer wall. If the roof 125 and the corner S2 of the outer wall have the reinforcing member 42, the strength of the house 100 against buoyancy is improved, and the strength of the house 100 against resistance generated by the tsunami is improved.

  FIG. 4 is a cross-sectional view showing the housing structure of the BB horizontal cross section of FIG. As shown again in FIG. 4, the outer wall includes short outer wall portions 121 and 122 and two long outer wall portions 123 and 124 that connect these short outer wall portions 121 and 122. The living unit 102 includes a garage 410 inside.

  Here, the short outer wall parts 121 and 122 whose horizontal cross-sectional shape is a semicircular arc are illustrated as an example. That is, the center angle α of the line segment obtained by connecting the arc center C and both ends of the arc is 180 degrees. However, the present invention is not limited to this, and the center angle α may be 90 degrees or more and 180 degrees or less. Further, as long as the drag from the tsunami is reduced, the outer peripheries of the cross sections of the short outer wall portions 121 and 122 may be curved surfaces that draw ellipses or other curves.

  The longitudinal outer wall portions 123 and 124 include a front door 401, a window 402, and a garage entrance 403. Moreover, the entrance 401, the window 402, and the garage entrance 403 are provided with door bodies (including window glass and shutters) 411, 421, and 431, respectively. The entrance 401 includes a door body 411 attached to an entrance frame (opening) that is integrally fixed to the longitudinal outer wall portions 123 and 124. The window 402 includes a door body 421 attached to a window frame (opening) that is integrally fixed to the longitudinal outer wall portions 123 and 124. Therefore, the entrance 401, the window 402, and the garage entrance 403 can be opened and closed by moving the door bodies 411, 421, and 431. All of the entrance 401, the window 402, and the garage entrance 403 are disposed on the inner side of the living part 102 with respect to the outermost surfaces of the longitudinal outer wall parts 123 and 124. Therefore, recessed spaces (gap regions) 412, 422, and 432 are formed on the outside of the door bodies 411, 421, and 431, which are recessed to the inside of the living portion 102 from the outer surfaces of the long outer wall portions 123 and 124.

  Outside the entrance 401, the window 402, and the garage entrance 403, shutter units (watertight structures) 404, 405, and 406 that prevent water from entering the living unit 102 are provided.

  The house 100 of this embodiment having the above-described structure is excellent as a tsunami countermeasure house. For example, the house 100 includes short outer wall portions 121 and 122 whose horizontal cross-sectional shapes are arc shapes at both ends in the longitudinal direction X (see FIG. 4). Therefore, no matter what direction the tsunami push wave or pull wave rushes toward the house 100, the tsunami will flow along the outer surfaces of the short outer wall portions 121 and 122 having a circular arc shape in cross section. . Thereby, the magnitude | size of the drag which arises in the house 100 which received the tsunami is suppressed, and it is prevented that the house 100 is destroyed without being able to support the drag.

  The house 100 of the present embodiment has a structure in which the magnitude of the drag generated by the direction of flow of these fluids is different when placed in a fluid such as a tsunami or wind. Therefore, when paying attention to the tsunami, it is preferable to construct the tsunami so that the direction in which the drag generated when the tsunami is received is minimized. However, since a tsunami is a natural disaster, it is not always easy to predict the direction of a tsunami and determine the direction of a house to be built.

  Thus, various studies were made on the direction of the tsunami, and it was found that the direction of the pulling wave direction Tb was easier than the prediction of the direction of the pushing wave. That is, the pulling wave is a returning wave after the pushing wave, and therefore tends to flow from a high place to a low place according to the height difference of the ground surface. And, when a pulling wave rushes, there is a tendency for the number of obstacles to be smaller than when a preceding rushing wave rushes. Therefore, it can be said that the pulling wave also has a high tendency to follow the height difference of the ground surface. Therefore, it can be said that the direction of the pulling wave at the construction position of the house 100 matches, for example, the direction orthogonal to the contour line at this position.

  In addition, on flat land adjacent to the sea, it is considered that not only the direction of the push wave but also the direction of the pull wave can be predicted relatively easily. In such an area, it can be said that both the direction of the push wave and the direction of the pull wave coincide with the direction perpendicular to the contour line at the house construction position.

  Therefore, when constructing the house 100 of the present embodiment, first, the direction of the tsunami push wave and the pull wave is predicted. Then, the direction of the longest line segment LX obtained by connecting both ends of the longest part of the residential part of the house matches the direction of the push wave and the pull wave when the tsunami rushes to the house construction site. It is preferable to construct.

  The house 100 is constructed in a state where the direction of the longest line segment LX matches the direction of the tsunami wave. Then, the pushing wave of the tsunami that has rushed flows from the one short outer wall portion 121 to the other short outer wall portion 122 in the longitudinal direction of the house 100, and the generated drag is suppressed. Also, the house 100 is constructed in a state where the direction of the longest line segment Lx matches the direction of the tsunami pulling wave. Then, the tsunami wave will flow in the longitudinal direction X of the house 100 from the other short outer wall portion 122 side to the one short outer wall portion 121 side, and is generated as in the case of the push wave. Drag is suppressed. Thus, if the generated drag is suppressed, the living part strength necessary to cope with the drag may be small, and the destruction of the living part 102 due to the tsunami wave is effectively prevented. it can.

[Configuration of shutter unit]
5A and 5B are internal configuration diagrams for explaining the frame structure of the shutter unit 404. FIG. As shown in FIG. 5A, the shutter unit 404 includes a rectangular frame portion 501 attached to the outside of the entrance 401 in a watertight manner, a lifting plate (elevating body) 504 that can be raised and lowered in the frame portion 501, and a lower portion of the frame portion 501. And a storage portion 505 for storing the lifting plate 504 attached integrally on the side. The elevating plate 504 is a watertight hollow rectangular plate-like body, and has a specific gravity lighter than that of water as a whole, and moves up and down according to the height of the water.
The opening of the living part 102 includes a door body 411 that opens and closes the opening. The watertight structure provided in the opening includes an elevating body 504 disposed outside the opening. The elevating body 504 can be elevated to a closed position that covers the door body 411 from the outside and an open position where the door body 411 is exposed to the outside. The lift body 504 in the closed position makes a gap region 412 that is a space between the lift body 504 and the door body 411 watertight with respect to the outside.

  The storage unit 505 is embedded in the lower part of the entrance (under the ground). The frame part 501 forms an opening 502, and a person who enters and exits the living part 102 of the house 100 can go through the opening 502 to the entrance 401.

  In the house 100 of the present embodiment, the inflow of water from the outside world to the outer wall recess in front of the entrance is limited to a route passing through the opening 502. Therefore, if the opening 502 is closed, the inflow of water from the outside to the outer wall recess in front of the entrance can be prevented.

  The frame portion 501 includes left and right vertical frame portions 511 and 512 that extend vertically, and an upper frame portion 513 that is connected to the upper ends of the vertical frame portions 511 and 512. Each of the vertical frame portions 511 and 512 and the upper frame portion 513 has a U-shaped groove shape in a cross section orthogonal to the longitudinal direction, and the groove-shaped opening is directed to the opening 502. That is, the upper frame portion 513 and the vertical frame portions 511 and 512 have a U-shaped configuration having an opening for taking in the elevating plate 504 on the inner side, like the outer rubber of the tire, and the upper side of the opening portion 502. Surrounding. The storage portion 505 is embedded so as to have a height equal to or lower than the floor surface height Gd of the entrance portion outside the entrance. The elevating plate 504 can be moved up and down between a position 504a in the storage portion 505 and a position 504b in the frame portion 501 (indicated by a two-dot chain line). When the elevating plate 504 is located at the retracted position, the upper end of the elevating plate 504 is not higher than the height position of the upper end of the storage unit 505.

  A packing 503 is continuously attached to the upper ends of the frame portion 501 and the storage portion 505 so as to surround the periphery of the opening portion 502. The packing 503 is an annular member made of a flexible rubber material. When the packing 503 and the elevating plate 504 at the raised position 504b are in close contact with each other, the opening 502 can be sealed watertight.

  As shown in FIG. 5B, the frame portion 501 includes an inner plate portion 501a, an outer plate portion 501b arranged in a state of facing the outer side, and further includes an upper plate portion 501c. A holding portion 551 is attached to the inner surface of the inner plate portion 501a, and a packing 503 is attached to the holding portion 551. The cover 558 is provided in the frame portion 501 around the opening 502, and reduces the gap between the frame portion 501 and the lifting plate 504. When foreign matter is mixed in the tsunami seawater, foreign matter larger than this gap is prevented from entering the inside. As a result, it is possible to prevent intrusion of foreign matter that may hinder internal operation.

  The storage portion 505 has a bag-like configuration including an inner plate portion 505a disposed on the entrance side and an outer plate portion 505b disposed so as to face the outside thereof, and having an opening at the upper end. The elevating plate 504 can be stored in the hollow portion 550 of the storage portion 505. The storage unit 505 further includes a flip-up step board 559 at the upper end. In a state where the tread plate 559 is closed, the upper end opening of the storage unit 505 is in a closed state, and a person who enters and exits the entrance does not reach the upper end of the storage unit 505.

  The tread plate 559 changes its angle upward about the axis as the elevating plate 504 rises (illustrated by a dotted line 559a in FIG. 5B), and the elevating plate 504 can be smoothly slid into the frame portion 501 when ascending. ing. When the elevating plate 504 descends and fits in the storage portion 505 again, the tread plate 559 rotates downward to return to the original position and closes the opening of the storage portion 505.

  As shown in FIG. 5B, a lower end stopper 553 for positioning the lowering limit position of the elevating plate 504 at the retracted position (position indicated by the solid line in FIG. 5B) is installed in the storage portion 505. In addition, an upper end stopper 555 that restricts the ascending limit position of the elevating plate 504 to a sealed position (a position indicated by a two-dot chain line in FIG. 5B) is installed on the lower surface of the upper plate portion 501c. By these stoppers 553 and 555, the lifting range of the lifting plate 504 is regulated.

  In addition, it is preferable that the height of the entrance floor Gd is higher from the ground G, and more preferably 200 mm or more. The ground G mentioned here is the ground outside the shutter unit 404 installed in front of the entrance (the ground G in FIG. 3). If the entrance floor Gd is higher than the ground, the water intake 554 can be provided in the storage portion 505 of the shutter unit 404. If there is a water intake 554, a water intake channel Gr connecting the entrance floor surface Gd and the opening of the stepped portion of the ground G from the water intake 554 can be formed. With this intake channel Gr, water can be taken into the hollow portion 550 of the storage portion 505 of the shutter unit 404 before the water level reaches the height of the entrance floor Gd. As a result, when the water level rises, water can be quickly taken into the storage portion 505, so that the lift plate 504 can be quickly raised according to the rise in water level.

  6A, 6 </ b> B, and 7 are internal configuration diagrams for explaining a slide mechanism of the elevating plate 504 between the frame portion 501 and the storage portion 505. Although omitted in FIG. 5 to clearly show the frame structure of the shutter unit 404, FIGS. 6A, 6B, and 7 guide the lifting operation of the lifting plate 504 provided in the frame portion 501 and the storage portion 505. Guide rollers 611, 612, 613, and 614 (see FIG. 6) are disclosed.

  The guide roller 603 is in contact with the inner guide roller 611 that is in contact with the inner side surface (entrance side surface) 541 of the elevating plate 504, the outer guide roller 612 that is in contact with the outer side surface 542 of the elevating plate 504, and the left and right side surfaces of the elevating plate 504. This is a lateral guide roller 613. By providing a plurality of these guide rollers 611, 612, and 613, the elevating plate 504 can be raised and lowered smoothly.

  8A, 8B, and 8C are diagrams for explaining the detailed structure of the packing 503. FIG. As shown in FIG. 8A, the annular packing 503 includes a root portion 801 that is fixed to the inner plate portion 541 of the frame portion 501 in a watertight state, and a lip portion 802 that protrudes from the root portion 801.

  The lip portion 802 has an elongated cross-sectional shape and a tapered shape, and the tip is curved outward (on the opposite side to the opening 502). Therefore, the inner side surface 821 that is one side surface of the lip portion 802 is a surface having a convex section, and the outer side surface 822 that is the other side surface is a surface having a concave section.

  And the convex inner side surface 821 of the lip | rip part 802 is located outside the position of the inner side surface 541 of the raising / lowering board 504 over a perimeter in the natural state like FIG. 8A. On the other hand, when the elevating plate 504 is raised, the packing 503 contacts the elevating plate 504 as shown in FIG. 8B. As described above, since the packing 503 is disposed so as to surround the opening 502, when the lifting plate 504 comes into contact with the entire circumference of the packing 503, the opening 502 is closed and the opening 502 is closed. Can be prevented from flowing into the outer wall recess 36b in front of the entrance. The packing 503 is a so-called self seal packing. That is, when the inflowing water comes into contact with the outer surface 822 that is the concave surface of the lip portion 802 of the packing 503, the lip portion 802 is pressed against the lifting plate 504 by water pressure (see arrow M1 in FIG. 8B). Thereby, the lip portion 802 is firmly attached to the lifting plate 504, and the watertight performance of the contact portion between the lip portion 802 and the lifting plate 504 is improved.

  Further, the lip portion 802 is curved until its tip is directed to the inner plate portion 541 side of the frame portion 501. Therefore, the elevating plate 504 can be smoothly raised to the sealed position (refer to the position indicated by the two-dot chain line in FIG. 5) without being caught by the tip of the lip portion 802.

  As shown in FIG. 8C, the seal structure by packing may be a double structure including an outer packing 503a and an inner packing 503b arranged so as to be surrounded by the outer packing 503a. With such a configuration, the water tightness is further improved.

  Next, a change in the position when the tsunami approaches the housing of the shutter unit 404 described above will be described in detail with reference to FIG.

  In the normal state, the lift plate 504 of the shutter unit 404 is located at the retracted position. And when a tsunami approaches the house 100, first, seawater flows into the storage part 505 from the water intake 554 (S901).

  In this state, a tsunami has come to the house 100, and the water level has reached the height of the draft line position of the lifting plate 504 located at the retreat position (a position below the upper end of the lifting plate 504 by H), and the water level has further increased. Then, the elevating plate 504 is in a state of floating in water. If it will be in this state, the raising / lowering board 504 will raise / lower automatically according to raising / lowering of a water level. That is, the elevating plate 504 moves up and down in a state where the floating portion above the draft line (the portion having a length H from the upper end) always protrudes above the water surface. Therefore, water does not flow into the entrance 401 over the upper edge of the lifting plate 504.

  With the sea level rise of the tsunami, the lifting plate 504 rises along the plurality of guide rollers by buoyancy (S902). As the elevating plate 504 is raised, the tread plate 559 rotates upward and moves to the open position 559a (S903).

  When the elevating plate 504 gradually rises according to the water level of the tsunami, before the water level reaches the height of the upper packing 503, the upper portion of the elevating plate 504 first reaches the height of the upper packing 503 and the packing 503 It contacts the lip 802 (S904).

  When the elevating plate 504 comes into contact with the packing 503, the portion of the packing 503 where the elevating plate 504 is in contact is in a watertight state.

  Thus, in the shutter unit 404 used in the present embodiment, the floating portion of the elevating plate 504 that is always on the water surface is in contact with the packing 503 at a position higher than the water surface to ensure a watertight state. That is, the upper end of the region where the watertight state is ensured (the upper end of the lifting plate 504) is always higher than the water surface. Therefore, even if the water level fluctuates, the inflow of water from the opening 502 of the shutter unit 404 to the entrance 401 can always be prevented.

  When the water level further rises, the elevating plate 504 finally reaches the sealed position (S905), and the elevating plate 504 comes into contact with the entire circumference of the annular packing 503. Even in this state, water can be completely prevented from entering the entrance 401 from the opening 502 of the shutter unit 404. Thereafter, even when the water level Ms further rises and the house 100 becomes submerged, the state in which the inflow of water from the opening 502 into the house 100 is prevented is maintained.

  As described above, if the shutter unit is installed outside the entrance / exit of the entrance 401 or the like, even if a tsunami hits the house 100, the lifting plate 504 automatically rises according to the water level and enters the house 100 from the opening. The inflow of water can be reliably prevented.

  FIG. 10 is a diagram illustrating a configuration of the shutter unit 405 installed outside the window 402. The shutter unit 405 installed outside the window 402 is different in size, except that the storage unit 1001 is not in the ground but in the space under the window, and the intake port 1002 is at the bottom of the storage unit 1001. The structure and operation are the same as those of the shutter unit 404 described above. Also, the shutter unit 406 installed outside the garage entrance 403 has the same structure and operation as the shutter unit 404 outside the entrance, except that the size is different.

  When a large tsunami hits, the entire detached house 100 may be submerged. In this case, there is a possibility that water may enter the living unit 102 through the opening / closing opening of the entrance 401 or the window 402.

  In this regard, the house 100 of this embodiment includes the shutter units 404, 405, and 406 described above. Therefore, as the water level Ms rises, the elevating plate 504 rises, and the elevating plate 504 closes the opening of the shutter unit. Thereby, the watertight state in the residence part 102 is maintained. In addition, since the base part 101 and the residence part 102 of the house 100 are integrated, water does not enter from the boundary between the cloth base part 201 and the outer wall or the boundary between the roof 125 and the outer wall. Also in this point, the watertight state in the living part 102 is ensured.

  In the above embodiment, the number of shutter units 404 installed in front of the entrance is one, but a plurality of shutter units 404 may be installed. In this case, the second and subsequent shutter units are watertightly installed in the recessed space 412 between the door body 411 and the shutter unit 404 of the entrance 401 of the house of the above embodiment. Therefore, when installing a plurality of shutter units, it is preferable to increase the depth of the recessed space 412. A plurality of shutter units 406 in front of the garage entrance 403 are also preferable.

(Tsunami resistance principle)
When the living part 102 of the house 100 has water-tightness as described above, buoyancy acts on the house 100 when a tsunami is approached. And if the house 100 floats by the buoyancy which acts, the house 100 will be washed away easily. The house 100 of the present embodiment has a structure in which this point is taken into consideration, and has a structure in which the buoyancy acting on the submerged house is smaller than the gravity acting on the house 100.

  That is, the house 100 includes an anchor part 202 having a weight function as a part of the base part 101, and the weight (gravity acting on the house) is increased by providing the anchor part 202. Specifically, the base portion 101 includes an anchor portion 202 that makes the gravity Gw acting on the house 100 larger than the buoyancy Gf acting on the submerged house 100. This is because buoyancy is greatest when the entire house is submerged. Therefore, the house 100 of this embodiment does not float even if it becomes submerged.

  For example, whether or not the surplus weight W, which is a value obtained by subtracting the buoyancy Gf acting on the house 100 from the gravity Gw acting on the house 100, is a positive value. It can be judged by. The house 100 in which the surplus weight W has a positive value does not float even if it receives buoyancy.

  By the way, the buoyancy Gf is a vertically upward force and directly acts on the living part 102 of the house 100, particularly the roof 125 of the living part 102. However, in a normal use single-family house, since the weight received from the upper structure is lighter as the upper part is farther from the ground, the required strength is smaller as the upper part is received. For this reason, in a typical detached house, even if watertightness in a submerged state is ensured, there is a possibility that the roof that has received buoyancy Gf is destroyed. If destruction occurs, water flows into the living part from the destroyed part.

  About this point, in the house 100 of this embodiment, the roof 125 is comprised with the reinforced concrete, and it is prevented that the roof 125 is destroyed by the buoyancy Gf.

  The buoyancy acting on the roof 125 acts on the outer wall as an upward pulling force, and further acts on the foundation 101. In the house 100 of the present embodiment, the roof 125 and the outer wall are integrally formed. With this structure, even if buoyancy Gf (upward pulling force) acts on the boundary portion between the roof 125 and the outer wall, the boundary portion is prevented from being broken. In addition, since the fabric base portion 201 and the outer wall are integrally formed, even if buoyancy Gf (upward pulling force) acts on the boundary portion between the fabric base portion 201 and the outer wall, the boundary portion is prevented from being broken. it can.

  Thus, in the house 100 of the present embodiment, the roof 125 can be prevented from being broken, the boundary between the roof 125 and the outer wall can be prevented from being broken, and the boundary between the outer wall and the cloth foundation 201 can be prevented from being broken. Thereby, the water tightness of the resident part 102 is more reliably maintained.

  In addition, when a tsunami is received, there is a risk of the house falling over due to the force of the tsunami. As described above, since the buoyancy Gf acts on the house submerged by the tsunami, the force in the direction of the gravity Gw acting on the house is a force that offsets the buoyancy Gf from the gravity Gw, and is smaller than the gravity Gw. helpful. If the force in the direction of gravity Gw acting on the house decreases, the gravity moment Mg of the house also decreases. If gravity moment Mg becomes small, it will become easy to fall by the force of a tsunami.

  In this regard, the base portion 101 of the house 100 according to the present embodiment includes the flange portion 203 and has a large weight moment, and thus has excellent anti-tip performance.

  About the fall of the house 100 which received the tsunami, for example, based on the surplus weight W, the drag F acting on the house which received the tsunami, the height BH of the house, and the length BL in the longitudinal direction of the foundation of the house Can be considered. That is, when the following formula (1) is established, it can be determined that the house does not fall.

W> F × BH / BL Formula (1)
Further, whether or not the house 100 falls depending on whether or not a value (excess weight moment Wm) obtained by subtracting the fall moment Mp acting in the direction of turning the house 100 from the gravity moment Mg of the flooded house 100 is a positive value. Can be determined. Since the house 100 of this embodiment has the flange 203, the gravity moment Mg is increased, so that the value of the surplus weight moment Wm is maintained positive even if it receives a larger tsunami. Therefore, the fall is prevented.

  The gravitational moment Mg (kg · m) of the house 100 shown in FIG. 11 can be calculated from the following equation.

Mg = 0.5 × BL (m) × Gw (kg) Formula (2)
Further, the overturning moment Mp is a value obtained by multiplying the longitudinal length BL of the foundation of the house and the drag F, and as shown in the following equation, the longitudinal length BL of the foundation of the house, the density of the tsunami It can be calculated using ρ, tsunami velocity V, tsunami facing area S of the house, and drag coefficient CD.

Mp = 0.5 × BL × 0.5 × ρ × V × V × S × CD Formula (3)
Here, seawater density (1030 kg / m 3) can be used as the tsunami density ρ. Since the general seawater density can be said to be about 1020 to 1040 kg / m3, the seawater density is an intermediate value thereof. However, since a tsunami is usually a turbid flow, a value that takes that point into account may be used. For example, a value obtained by multiplying the seawater density value by a numerical value of 1.1 to 1.5 may be used as the tsunami density. As the tsunami velocity V, for example, a value of 5 to 20 m / s can be used. Furthermore, the tsunami-facing area S of the house is the maximum area of the cross section of the house that is perpendicular to the direction of the tsunami. For example, in the case of a rectangular parallelepiped-shaped house shown in FIG. 11, the tsunami facing area S is calculated by multiplying the height BH of the house by the maximum length BW in the width direction of the house.

  Further, the ratio of the length in the longitudinal direction X to the length in the width direction Y, that is, the length ratio of the house (BL / BW, see FIG. 11) is more preferably greater than 1.5, and more preferably 2 or more. . This is because the drag coefficient CD of the house against the tsunami can be lowered by increasing the length-to-short ratio. If the drag coefficient CD can be suppressed to a low level, the drag F acting on the house that has received the tsunami will be reduced, and it will be able to withstand a stronger tsunami. Further, the height BH of the house (see FIG. 11) is preferably 1.2 times or less the length BL in the longitudinal direction X of the foundation of the house. Such a house has high strength against drag.

[Modification of Embodiment]
In the house 100 described above, the horizontal cross-sectional shape (see FIG. 4) of the short outer wall portions 121 and 122 draws an arc, but may be a curved shape other than the arc or a curved shape. FIG. 12 shows another example of the horizontal cross-sectional shape of the outer wall portions 121 and 122.

  Examples of the horizontal cross-sectional shape of the short outer wall portions 121 and 122 of the outer wall include an oval 1201, an oval 1202, a long hexagon 1203, and an elongated rhombus 1205. When emphasizing ease of construction, a long hexagon or a long rhombus is considered preferable. However, if the drag force is minimized, the outer outer wall portions 121 and 122 of the outer wall are preferably curved outer surfaces, and the horizontal cross-sectional shape of the outer surfaces of the shorter outer wall portions 121 and 122 is an arc. It is more preferable.

  The arcs referred to here include arcs that constitute a part of the ellipse 1202 in addition to a typical arc that is a part of the perfect circle 1204. Accordingly, the horizontal cross-sectional shape of the short outer wall portions 121 and 122 of the outer wall is, for example, a case where the horizontal cross-sectional shape of the living portion 102 of the house 100 is an oval 1201, an oval 1202, and a circle 1204.

The drag coefficient CD is preferably 0.8 or less, and more preferably 0.6 or less. For example, the drag coefficient of a house whose horizontal cross-section having a long / short ratio of 2 is a long hexagon 1203 is 0.8. Similarly, the drag coefficient of an elliptical 1202 house having a length-to-short ratio of 2 is 0.6. Further, the drag coefficient CD of an oval house having a long / short ratio of 2 is 0.4. Thus, from the viewpoint of the drag coefficient, it can be said that the above-described long hexagonal shape, elliptical shape, and oval shape are preferable as the horizontal sectional shape of the house. Furthermore, in other words, a shape in which the value of drag per unit area acting on the tsunami facing surface of a house that has received a tsunami is smaller than 200 kgf / m ² is preferable. Also from this viewpoint, a house whose horizontal cross-sectional shape is a long hexagon, an ellipse, or an oval is preferable as a tsunami countermeasure house.

  In addition, the horizontal cross-sectional shape of the living part 102 is judged based on the cross-sectional shape in a suitable height position (one place or multiple places). Examples of the height position of the horizontal section include the intermediate height position of the living part, the intermediate height position of the first floor part, the intermediate height position of the second floor part if it is two stories, the ground height position adjacent to the ground, etc. Can be mentioned. Moreover, you may judge based on the horizontal cross-sectional shape of the height position for every meter from the ground.

  Further, as shown in FIG. 13, the short outer wall portions 121 and 122 of the house 100 may have arcs 1301 and 1302 in the upper half of the vertical section (for example, a two-story second floor portion). Further, it may have a shape in which the entire vertical section is an arc (not shown).

  In addition, the short outer wall portions 121 and 122 of the outer wall may have a shape in which the vertical portion S1 is inclined toward the center of the living portion 102 toward the upper end side thereof. In this case, the outer wall is inclined with the outer surface facing upward.

  Moreover, although the thickness is constant in the said embodiment, the living part 102 and outer wall of the house 100 are not restricted to such a shape. For example, the outer wall may have a shape (a diverging shape) in which the vertical cross-sectional shape becomes thicker toward the lower side (toward the base portion 101 side).

(About material)
Moreover, although the raw material of the foundation part 101 and the residence part 102 of the house 100 is reinforced concrete in the said embodiment, it is not restricted to this. As the material for these, a steel material whose main structural material is steel, a concrete material whose main structural material is concrete, and a composite material whose main structural material is steel material and concrete material can be used.

  As steel materials here, steel materials, such as a high-tensile steel plate, can be mentioned, for example. Since the composite material using this steel plate and this steel plate itself are excellent in water tightness, it can be said that, for example, if this point is noted, it is suitable as a material for the roof 125 of the living part 102.

  Further, examples of the composite material of steel and concrete here include reinforced concrete (RC) and prestressed concrete (abbreviated as PC). Examples of the prestressed concrete include prestressed concrete (Prestressed Reinforced Concrete (abbreviation: PRC)) and partially prestressed concrete (abbreviation: PPC). And as a method of building prestressed concrete, there can be mentioned, for example, a pre-tension method for tensioning a PC steel material before placing concrete and a post-tension method for tensioning a PC steel material after placing concrete. Since prestressed concrete has high strength against tensile force, it can be said that, for example, it is suitable as a material for the outer wall of the living part 102 if attention is paid to this point.

  Moreover, in the house 100 of this embodiment, as above-mentioned, each member which comprises the residence part 102 is integral, and the base part 101 and the residence part 102 are also integral. With respect to this point, in the present embodiment, whether adjacent members are integrated is determined based on the requirements listed below. That is, when one or more of the following two requirements are included, adjacent members are integral with each other.

  The first requirement is that the steel materials that are constituent elements of adjacent members are integral. The case where the steel materials of adjacent members are integral with each other is, for example, a case where a seamless steel material is used as the steel material of the adjacent members.

  The second requirement is that the concrete materials that are constituent elements of the adjacent members are integrated. The case where the concrete materials that are constituent elements of the adjacent members are integral with each other is, for example, a case where the concrete constituting the adjacent members is simultaneously placed.

Further, in the above embodiment, the base portion 101 is integrally configured by an integral placement method, but the method is not limited to this, and can be constructed by various methods.
(Effect of this embodiment)
As described above, since the water-tight structure is provided in the opening of the house, the intrusion of water from the opening into the living part is prevented, and the water in the living part is prevented. Moreover, since the volume of the living part is a volume where the buoyancy acting on the submerged house is smaller than the gravity acting on the house, it does not float even if the house is submerged. Residential areas are protected because houses that do not float are not easily toppled by the tsunami. Even victims evacuated from the tsunami can continue to live at home after the tsunami.

[Second Embodiment]
A house 1400 as a second embodiment of the present invention will be described with reference to FIG.

  The base portion 1401 of the house 1400 has a structure in which the soil constituting the ground is taken in as a part of the foundation. The base part 1401 shown in FIG. 14 is generally constructed as follows. First, a bowl-shaped foundation structure 1411 using a structural material such as a rust-proof reinforcing bar or steel frame is integrally formed in the ground of the site. The interior of the bowl-shaped basic structure 1411 has a structure in which a large number of structural materials such as reinforcing bars or steel frames are integrally formed in a columnar shape. It is preferable to construct so that the upper end of the bowl-shaped foundation structure 1411 is at the height of the ground. Moreover, it is preferable that the lower part of the foundation structure 1411 is buried in the ground and the upper part is exposed.

  Various shapes are conceivable as the shape of the foundation structure 1411, but a rectangular parallelepiped mesh shape shown in FIG. 14 is preferable. And it is preferable that the structural material is arranged not only in the outer peripheral portion of the foundation structure 1411 but also in the inside. With this structure, the strength of the foundation part 1401 after construction is improved, and deformation is more reliably prevented.

  Further, when forming the bowl-shaped foundation structure 1411, a board 1413 having rigidity, water permeability, and air permeability is disposed on the inner side 1412 of the bottom surface of the foundation structure 1411 and the entire inner circumference of the outer peripheral surface. Examples of the board 1413 used here include plastic and grating. Thereafter, ready-mixed concrete is poured into the exposed upper portion of the foundation structure 1411, and the foundation portion 1401 and the living portion 1402 are constructed by an integral placement method.

  If the foundation part 1401 is constructed in this way, the soil 1421 constituting the ground can be taken into the bowl-shaped foundation structure 1411, and the ground soil can be used as a part of the foundation. If a part of the ground can be used as a foundation, a heavier foundation can be made. You can also create foundations of the same weight using less concrete material.

[Third Embodiment]
A residence 1500 as a third embodiment of the present invention will be described with reference to FIG. The foundation 1501 shown in FIG. 15 is generally constructed as follows. First, a retaining wall 1503 surrounding the site is made. The retaining wall 1503 is formed by integrally forming a bottom portion 1532 and a peripheral wall 1531. The bottom portion 1532 and the lower portion of the peripheral wall 1531 are located in the ground, and the upper portion of the peripheral wall 1531 is exposed to the ground. The bottom 1532 is preferably provided with a through hole 1504 at the center, for example. Further, the upper part of the peripheral wall 1531 is preferably a curved surface whose outer surface is convex outward, and more preferably the horizontal cross-sectional shape is an arc shape.

  Next, soil 1421 is filled into the retaining wall 1503 and, at the same time, a foundation portion 1501 similar to the foundation portion 101 shown in FIG. 14 is constructed inside the retaining wall. In addition, since the construction method of this part is the same as the foundation of FIG. 14, the detailed description is abbreviate | omitted here. In addition, the outer surface of the retaining wall 1531 may be inclined so as to expand toward the bottom.

  In the base portion 1501 including such a retaining wall 1503, the height of the upper end surface of the retaining wall 1503 is the height of the substantial site of the house, so that the house can be constructed at a higher position. Being able to build a house in a high position is extremely excellent as a tsunami countermeasure.

[Fourth Embodiment]
A house 1600 as a fourth embodiment of the present invention will be described with reference to FIG. The height position of the site surface Gh where the house 1600 is constructed is higher than the ground G. Like the base part 1601, you may comprise a composite material with structural materials, such as a reinforcing bar, which comprises the outer periphery of the bowl-shaped foundation structure 1603, and concrete. That is, the outer periphery of the base portion 1601 may be surrounded by the composite material 1604 of a structural material such as a reinforcing bar and concrete. In this case, the concrete may not be poured into the center of the bottom surface of the foundation structure 1603, and an opening 1631 that ensures air permeability and water permeability between the soil inside the foundation structure and the outside soil may be formed. .

  Then, a communication hole communicating with the soil region contained in the foundation structure is formed in the concrete portion above the foundation portion 1601. This communication hole has air permeability and water permeability. With such a structure, the base portion 1601 can be made stronger.

[Fifth Embodiment]
A house 1700 as a fifth embodiment of the present invention will be described with reference to FIG. When the height of the site surface Gh is higher than the ground G, the foundation hollow portion 1701 may be formed at a position inside the foundation and above the ground G, as shown in FIG.

  The basic hollow portion 1701 has an opening a at one end, and can be used as a parking space, for example. A shutter unit 406 is installed at one end opening of the basic hollow portion 1701. If the shutter unit 406 is installed, intrusion of water into the basic hollow portion 1701 can be prevented and the objects in the basic hollow portion 1701 can be protected from water damage as in the above-described embodiment. Note that the basic hollow portion 1701 may be in a through state where both ends are open. In this case, it is preferable to install a shutter unit in both openings.

[Sixth Embodiment]
A house 1800 as a sixth embodiment of the present invention will be described with reference to FIG. 18 is constructed by a so-called chemical solution injection method. The chemical solution injection method is generally a kind of ground improvement method in which a chemical solution is injected into the ground to lower the water permeability of the ground or to strengthen the ground. Since it is a construction method used so far, detailed description thereof is omitted here. And the chemical | medical solution used here is for solidifying the soil which comprises the ground, for example, a main body is a water glass type chemical | medical solution, and 2 to 3 types of hardening materials and adjuvants are added to this. It has been done. In addition, the time required for the ground solidification by this chemical | medical agent can be adjusted to arbitrary time by adjusting the component of a chemical | medical solution.

  The foundation 1801 shown in FIG. 18 is generally constructed as follows. First, a large number of structural materials composed of rust-proof reinforcing bars or steel frames are embedded in the ground of the site. In this embodiment, a pile 1803 is embedded. As a method of embedding the pile 1803, various methods such as driving and insertion can be exemplified. As a pile (structural material) 1803, what has an unevenness | corrugation in an outer peripheral surface is preferable. Examples of the material having irregularities on the outer surface include a spiral pile.

  Then, the chemical | medical solution of the component mentioned above is inject | poured into the ground of the part in which the pile 1803 was embedded. Then, the ground is solidified by the action of the chemical solution, and the solidified ground and the spiral pile 1803 are firmly integrated. In other words, the ground and the lower part of the foundation part 1801 form a unitary block.

  Then, concrete is poured from the upper part of the foundation part 1801 into the outer wall of the living part 1802 and the roof 125, and the foundation part 101e, the outer wall, and the roof 125 are constructed by an integral driving method.

  Since the foundation part 1801 constructed in this manner is in an integrated state with the ground, it is possible to improve the strength against the drag and buoyancy acting on the house that has received the tsunami.

[Seventh Embodiment]
The base portion 101 of the house according to the first embodiment described above includes an overhanging portion such as the collar portion 203, thereby increasing the installation area with the ground G. Then, by increasing the installation area of the base portion 101 and the ground G, it is possible to more reliably prevent the house 100 from being washed away by the tsunami.

  However, when the ground is weak, there is a possibility that sufficient force that can be opposed to the sink is not generated between the ground G and the ground G. In this regard, if the foundation of the house is provided with a plurality of piles in the ground, the tsunami will prevent the house from being washed away more reliably. In addition, as a pile, the thing extended below toward the ground from the anchor part of the foundation can be mentioned, for example. As a method for forming the pile, for example, a driving method can be cited.

  This method will be described with reference to FIG. As shown in FIG. 19, the foundation 1901 of the house 1900 includes a plurality of piles 1911 that have digged into the ground. The base 1901 is an integrated pile 1911 extending downward. This pile 1911 is driven into the underground rock mass GR.

  The base portion 1901 is roughly constructed as follows. First, a depression is formed in the site, and a plurality of reinforced concrete piles 1911 are driven toward the rock GR. Next, a rectangular parallelepiped base structure 1912 is formed above the pile 1911. At this time, it is preferable to connect the bowl-shaped basic structure 1912 and the pile 1911. As a method of connecting the bowl-shaped foundation structure 1912 and the pile 1911, for example, it is conceivable to form a reinforcing bar on the pile 1911 side made of reinforced concrete and a reinforcing bar on the foundation structure 1912 side. With such a structure, the base 1901 and the pile 1911 can be integrated.

  Thereafter, the ready-mixed concrete is poured into the foundation structure 1912 to construct the foundation 1901, and the ready-mixed concrete is poured into the outer wall and the roof 1925 of the living part 1902. Install 1925.

  Since the foundation 1901 constructed in this way is in an integrated state with the ground, it is possible to improve the strength against drag and buoyancy acting on the tsunami-dwelling house. That is, if the foundation 1901 includes such a pile 1911, it is possible to more reliably prevent the house that has received the tsunami from being washed away.

  Further, the house 1900 includes a skylight 1909 on the roof 1925. The roof 1925 is a portion that first appears on the water surface when the water level drops. Therefore, if there is a skylight 1909 at this position, when the water level falls, it is possible to ventilate quickly, and the skylight 1909 can go out of the living part 1902.

DESCRIPTION OF SYMBOLS 100 ... Housing, 101 ... Foundation, 21 ... Anchor part, 22 ... Cloth foundation part, 23 ... Buttocks,
102 ... Living part, 121, 122 ... Short outer wall part, 123, 124 ... Longitudinal outer wall part, 125 ... Roof 301 ... Middle part,
401 ... Entrance, 402 ... Garage entrance, 403 ... Window, 404 ... Shutter unit at entrance, 405 ... Shutter unit at window, 406 ... Shutter unit at garage entrance,

Claims (6)

A structure comprising a foundation part and a living part fixedly attached to the foundation part,
The living part includes a watertight structure that prevents opening of water from the opening to the living part and includes an openable / closable opening used for communication inside and outside the living part,
Said base portion, than the buoyancy acting on the structure of the submerged state, have a weight such as gravity acting on the structure is increased,
The opening of the living part includes a door body that opens and closes the opening,
The watertight structure provided in the opening includes an elevating body disposed outside the opening,
The lifting body can be raised and lowered between a closed position that covers the door body from the outside and an open position where the door body is exposed to the outside world,
The said lifting body of the said closed position makes the clearance gap area which is the space between the said lifting body and the said door body watertight with respect to the external environment. The structure according to claim 1 , wherein the elevating body has a specific gravity lighter than water and moves up and down according to a water level outside the living part . The upper part of the foundation portion, the structure according to claim 1 or 2, further comprising a flared overhang toward the outside of the bottom surface area of the residence portion.   The outer wall of the living part is provided with a short outer wall part projecting outward at two positions, a first position to receive a tsunami wave and a second position to receive a pulling wave. The structure according to any one of claims 1 to 3, wherein the two short outer wall portions are connected by two long outer wall portions.   The structure according to claim 4, wherein the outer periphery of the horizontal section of the short outer wall portion is an arc having a central angle of 90 degrees or more and 180 degrees or less.   The structure according to claim 4 or 5, wherein the opening is formed only in the longitudinal outer wall.

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