JP2022128146A - floating shelter - Google Patents

Abstract

To provide a floating shelter easily maintaining a floating state in a tsunami and the like by which a great amount of debris etc. is washed away.SOLUTION: A floating shelter (1) floating on a water surface accommodating evacuating people includes: a main unit (10) provided with a conical shape side surface (10a) having a diameter becoming smaller from above to below, an interior space (40) for accommodating the evacuating people, and a hatch (11) as an entrance for the evacuating people; a canopy (20) for covering a top end opening of the main unit (10); and a ballast (45) loaded inside the interior space (40). The ballast (45) is adjusted so that a draft position of the floating shelter (1) is located approximately at a top end position (A) of a side surface (10a) of the main body (10).SELECTED DRAWING: Figure 1

Description

TECHNICAL FIELD The present invention relates to a floating shelter that accommodates evacuees during a tsunami or flood.

A floating shelter that accommodates evacuees and floats on the surface of water has been proposed as equipment or facilities for evacuating in the event of a tsunami or flood. Patent Literature 1 discloses a floating shelter with a substantially egg-shaped hollow structure. Patent Document 2 discloses a tsunami evacuation facility having a hollow body with a spherical upper portion and an inverted cone-shaped lower portion, and a reinforcing strut and diagonal members attached to the outside of the hollow body and a float at the lower portion. there is

Japanese Patent No. 3541197 JP 2015-54565 A

Large tsunamis and floods carry a large amount of debris with them, and floating shelters may collide with them and receive a large impact or damage. In the case of the substantially egg shape of Patent Document 1, most of the outer surface is inclined outward from the top to the bottom. tends to sink. In addition, when a complicated strut or the like is attached to the outside of the hollow body as in Patent Document 2, debris and the like are entangled and the stable floating state is hindered, and it is easy to get caught in obstacles. There is also the risk of being dragged into

In view of the above circumstances, it is an object of the present invention to provide a floating shelter that can easily maintain a stable floating state on the surface of the water even in the event of a tsunami or flood in which a large amount of rubble or the like flows together.

In order to achieve the above objects, the present invention provides the following configurations. Numerals in parentheses are reference numerals in the drawings, which will be described later.

- An embodiment of the present invention is a floating shelter (1) for housing evacuees, comprising:
A main body (10) comprising a conical side surface (10a) whose diameter decreases from top to bottom, an internal space (40) for accommodating evacuees, and a hatch (11) for egress and egress of evacuees. When,
a canopy (20) covering the upper end opening of the main body (10);
a ballast (45) mounted within the interior space (40);
The ballast (45) is adjusted so that the draft position of the floating shelter (1) is substantially the upper end position (A) of the side surface (10a) of the main body (10).
- Another aspect of the invention is a floating shelter (1) for housing evacuees, comprising:
Equipped with a truncated conical or cylindrical side surface (10a) whose diameter decreases from top to bottom, an internal space (40) for accommodating evacuees, and a hatch (11) for egress and egress of evacuees. a main body (10);
a canopy (20) covering the upper end opening of the main body (10);
a ballast (45) mounted within the interior space (40);
The ballast (45) is adjusted so that the draught position of the floating shelter (1) is substantially the upper end position (A) of the side surface (10a) of the main body (10), and
The bottom surface (10b) of the main body (10) has an upward convex shape that gradually rises from the lower end position (B) of the side surface (10a) to the central axis (C) in a longitudinal section including the central axis (C). It is a surface of revolution obtained by rotating a curve around the central axis (C).
- Yet another aspect of the present invention is a floating shelter (1) for housing evacuees, comprising:
Equipped with a truncated conical or cylindrical side surface (10a) whose diameter decreases from top to bottom, an internal space (40) for accommodating evacuees, and a hatch (11) for egress and egress of evacuees. a main body (10);
a canopy (20) covering the upper end opening of the main body (10);
a ballast (45) mounted within the interior space (40);
The ballast (45) is adjusted so that the draught position of the floating shelter (1) is substantially the upper end position (A) of the side surface (10a) of the main body (10), and
The bottom surface (10c) of the main body (10) has an upward convex shape that gradually descends from the lower end position (B) of the side surface (10a) to the central axis (C) in a longitudinal section including the central axis (C). It is a surface of revolution obtained by rotating a curve around the central axis (C).
- In the above aspect, it is preferable to further have a plurality of stabilizing plates (12) protruding radially near the lower end of the bottom surface (10c).
- In the above aspect, when the side surface (10a) has a truncated cone shape, the diameter (D1) at the lower end position (B) of the side surface (10a) is half the diameter (D) at the upper end position (A) Greater than one is preferred.
- In the above aspect, the vertical length (H) from the upper end position (A) to the lower end position (B) of the side surface (10a) is 1.5 times the diameter (D) at the upper end position (A) ~ 2.5 times is preferred.
- In the above aspect, it is preferred that the ballast (45) is composed of a large number of ballast solids.
- In the above aspect, a ventilation opening (24) provided in the main body (10) or the canopy (20);
It is preferable to further comprise a trigger valve provided for opening and closing the ventilation opening (24) and closing upon detection of vibration.
- In the above embodiment, it is preferred to further have a hanging hook (22) attached to the surface of the canopy (20) for hanging the floating shelter (1) by heavy machinery.
- In the above embodiment, it is preferred to further have an identification mark (23) attached to the surface of the canopy (20).
- In the above aspect, it is preferred to further comprise a second hatch (21) provided in the canopy (20).

According to the floating shelter of the present invention, the main body has a cone-shaped side surface whose diameter decreases from top to bottom, or a truncated cone-shaped or cylindrical side surface with a curved bottom surface that is convex upward. and the draft position is adjusted to be almost at the upper end of the side, so in the event of a tsunami or flood that causes a large amount of debris to flow, debris that collides with the side or bottom will float. Since an upward force is applied to the shelter, it becomes easier for the floating shelter to maintain a stable floating state on the water surface.

FIG. 1 is an external perspective view schematically showing a floating shelter according to a first embodiment of the present invention. FIG. 2(a) is an external perspective view schematically showing a floating shelter according to a second embodiment of the present invention, and FIG. 2(b) is a sectional view taken along line II of (a). FIG. 3(a) is an external perspective view schematically showing a floating shelter according to a third embodiment of the present invention, and FIG. 3(b) is a cross-sectional view taken along line II-II of (a). Fig. 4(a) is an external perspective view schematically showing a modified floating shelter of the second embodiment, and Fig. 4(b) schematically showing a modified floating shelter of the third embodiment. FIG. 5 is an external perspective view schematically showing a modification of the embodiment of FIG. 4(b). FIG. 6 illustrates the state in which the floating shelter according to the present invention floats on the surface of the water. FIG. 7 schematically shows forces of the same magnitude applied at various angles to the side surface of the main body and component forces thereof. FIG. 8 is a schematic perspective view showing an example of the storage state of the floating shelter of the present invention when not in use. FIG. 9 is a schematic vertical cross-sectional view showing a configuration example inside the internal space of the floating shelter of the first embodiment. FIG. 10 is a diagram schematically showing the III-III section of FIG. FIG. 11 is a diagram schematically showing an example of a form in which the floating shelter of the present invention is connected to a house for storage. FIG. 12 is a diagram schematically showing an example of a form in which the floating shelter of the present invention is transported by vehicle.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In addition, in the drawings of each embodiment, the same or similar elements are indicated using the same or similar reference numerals.

FIG. 1 is an external perspective view schematically showing a floating shelter (hereinafter sometimes simply referred to as a “shelter”) according to a first embodiment of the present invention. The floating shelter 1 can accommodate evacuees and float on the surface of the water when the water level rises in a normally waterless place during a tsunami or flood. The shelter 1 has a main body part 10 and a canopy part 20 thereon as main parts.

The body portion 10 of the first embodiment has a conical side surface 10a whose diameter decreases from top to bottom. Thus, the base of the normally oriented cone is at the upper end position A of the body portion 10, and the apex of the normally oriented cone is at the lower end position B of the body portion 10a. The body part 10 is a hollow body with an open upper end, and has an internal space 40 for accommodating evacuees. A configuration example inside the internal space 40 will be described later. The side surface 10a is the outer surface of the sidewall formed with a predetermined thickness and material. Hatches 11 for evacuees to enter and exit are provided at appropriate locations on the side walls.

When the side surface 10a of the main body 10 has a conical shape, the vertical length H from the upper end position A to the lower end position B of the side surface 10a is 1.5 to 2.5 times the diameter D at the upper end position A. Preferably. In the illustrated example, the length H is approximately twice the diameter D.

The canopy part 20 continues to the upper end of the side wall of the main body part 10 so as to cover the upper end opening of the main body part 10 . The canopy 20 may be substantially dome-shaped, for example, as shown. The shape of the canopy portion 20 is not limited to this, and may be, for example, a cylindrical shape, a conical shape, or a truncated cone shape. The canopy part 20 is also a hollow body, and has an internal space that is integrally continuous with the internal space 40 . A preliminary second hatch 21 is preferably provided at the zenith of the canopy section 20 .

In addition, since the structure for ensuring the airtightness and durability of the floating shelter 1 is a known technology, it will not be described in detail in this specification.

Furthermore, a ballast 45 serving as a weight is mounted in the internal space 40 of the main body 10 . Preferably, the ballast 45 is mounted on the lower portion of the body portion 10 of the shelter 1 . This lowers the center of gravity of the shelter 1, making it easier to maintain the posture shown in the figure.

The shelter 1 is buoyant in water. The buoyancy is proportional to the product of the submerged volume of the shelter 1, that is, the volume of the portion below the draft position and the density of the water. The buoyancy balances the weight of shelter 1. Therefore, the draft position of the shelter 1 varies depending on the weight of the shelter 1 . In the present invention, the weight of the shelter 1 itself and the weight of all evacuees who are going to ride in it are added, and the weight of the ballast 45 is adjusted in advance in consideration of it. In that case, the ballast 45 is adjusted so that the draft position of the shelter 1 is the upper end position A of the side surface 10 a of the main body 10 . The draft position does not have to be strictly the upper end position A, and may be about this position as the target.

The ballast 45 is composed of a large number of ballast individuals 45a. For example, a combination of multiple ballast pieces 45a of the same weight may be used. In another example, a combination of multiple types of ballast solids with different weights may be used. The weight of ballast 45 can be adjusted by the number and/or type of ballast individuals 45a. The ballast piece 45a can be, for example, a sealed container filled with water or liquid, or it can be a metal weight.

When the upper end position A of the side surface 10a of the body portion 10 is at the draft position, rubble or the like collides with the submerged side surface 10a of the body portion 10 . Therefore, the reversed conical surface of the side surface 10 a has the function of receiving the impact force of colliding rubble or the like and converting the impact force into an upward force on the shelter 1 . This action will be described in detail with reference to FIG.

Preferably, shelter 1 is provided with ventilation openings 24 . In the illustrated example, the ventilation openings 24 are provided in the wall of the canopy section 20 , but they may be provided in the side walls of the main body section 10 . The vent 24 is open until the shelter 1 starts to float, and is valved so that it closes at the start of the float. Preferably, a trigger valve is used that automatically closes upon detecting vibration of the shelter 1 caused by an earthquake, tsunami, or the like. It is preferable that the air (oxygen) in the shelter 1 is sufficient for breathing until a predetermined number of evacuees are rescued (for example, several hours to about one day).

Preferably, a hanging hook 22 is attached to the surface of the canopy portion 20 for hanging the shelter 1 by heavy machinery. In the illustrated example, a pair of hanging hooks 22 are attached diagonally.

Preferably, an identification mark 23 is attached to the surface of the canopy section 20 . This is a sign for identifying the shelter 1 or the evacuees therein, and is useful for rescue.

FIG. 2(a) is an external perspective view schematically showing a floating shelter according to a second embodiment of the present invention, and FIG. 2(b) is a sectional view taken along line II of (a). However, only the outline shape of the shelter 1 is shown here, and the other constituent elements shown in FIG. 1 are omitted.

The body portion 10 of the second embodiment has a frustoconical side surface 10a whose diameter decreases from top to bottom. Accordingly, the normally oriented lower surface of the truncated cone is the upper end position A of the body portion 10, and the normally oriented upper surface of the truncated cone is the lower end position B of the body portion 10a. As in the first embodiment, the main body 10 is a hollow body with an open top, has an internal space for accommodating evacuees, and has a canopy 20 covering the top opening.

When the side surface 10a of the main body 10 has a truncated cone shape, the vertical length H from the upper end position A to the lower end position B of the side surface 10a is 1.5 to 2.5 times the diameter D at the upper end position A. Double is preferred. In the illustrated example, the length H is approximately twice the diameter D. Moreover, it is preferable that the diameter D1 at the lower end position B of the side surface 10a is 1/2 or more of the diameter D at the upper end position A. In addition, these numerical values are not limited to this range.

The main body part 10 of the shelter 1 of the second embodiment has a characteristically shaped bottom surface 10b. The bottom surface 10b is an upwardly convex curved surface. The bottom surface 10b of the main body 10 draws an upwardly convex curve that gradually rises from the lower end position B of the side surface 10a to the central axis C in the longitudinal section including the central axis C shown in FIG. 2(b). This curve is, for example, a circular arc, an elliptical arc, a parabola, or the like. The bottom surface 10b is a surface of revolution obtained by rotating the upwardly convex curve in this cross section by 360° around the central axis C with the generatrix.

FIG. 3(a) is an external perspective view schematically showing a floating shelter according to a third embodiment of the present invention, and FIG. 3(b) is a cross-sectional view taken along line II-II of (a). However, only the outline shape of the shelter 1 is shown here, and the other constituent elements shown in FIG. 1 are omitted.

A body portion 10 of the third embodiment has a truncated cone-shaped side surface 10a whose diameter decreases from the top to the bottom, as in the second embodiment. Accordingly, the normally oriented lower surface of the truncated cone is the upper end position A of the body portion 10, and the normally oriented upper surface of the truncated cone is the lower end position B of the body portion 10a. As in the first and second embodiments, the main body 10 is a hollow body with an open upper end, has an internal space for accommodating evacuees, and the upper end opening is covered with a canopy 20. .

When the side surface 10a of the main body 10 has a truncated cone shape, the vertical length H from the upper end position A to the lower end position B of the side surface 10a is 1.5 to 2.5 times the diameter D at the upper end position A. Double is preferred. In the illustrated example, the length H is about 1.5 times the diameter D. Moreover, it is preferable that the diameter D1 at the lower end position B of the side surface 10a is 1/2 or more of the diameter D at the upper end position A. In addition, these numerical values are not limited to this range.

The body part 10 of the shelter 1 of the third embodiment has a bottom surface 10c with a characteristic shape. The bottom surface 10c is formed of an upwardly convex curved surface different from that of the second embodiment. The bottom surface 10c of the main body 10 draws an upwardly convex curve that gradually descends from the lower end position B of the side surface 10a to the central axis C in a longitudinal section including the central axis C shown in FIG. This curve is, for example, a circular arc, an elliptical arc, a parabola, or the like. The bottom surface 10c is a surface of revolution obtained by rotating the upwardly convex curve in this cross section by 360° around the central axis C about the generatrix.

In the second and third embodiments, since the main body 10 has the bottom surfaces 10b and 10c with characteristic shapes, these bottom surfaces 10b and 10c are also subjected to the impact force of debris in the water, in addition to the side surface 10a, and are sheltered. It acts as a surface that converts the upward force against 1. Therefore, the inclination of the truncated cone shape of the side surface 10a of the second and third embodiments may be approximately the same as the inclination of the cone shape of the first embodiment, but may be gentler than that of the first embodiment. This action will be described in detail with reference to FIG.

Fig. 4(a) is an external perspective view schematically showing a modified floating shelter of the second embodiment, and Fig. 4(b) schematically showing a modified floating shelter of the third embodiment. In these variants, the side surface 10a of the body 10 is cylindrical rather than frusto-conical. In these modified forms, the bottom surfaces 10b and 10c exclusively function as surfaces that receive the impact force of underwater debris or the like and convert it into an upward force on the shelter 1 . This action will be described in detail with reference to FIG.

FIG. 5 is an external perspective view schematically showing a modified floating shelter of the embodiment shown in FIG. 4(b). In this modified form, in the shelter 1, a plurality of stabilizing plates 12 are attached near the lower end of the bottom surface 10c of the main body 10 so as to project radially with their wide surfaces parallel to the vertical direction. A single stabilizer 12 is a substantially triangular plate-shaped member having a predetermined thickness and having a maximum width w and a height h. The maximum width w is about 1/4 of the diameter at the lower end position B of the body portion 10, and the height h is about 1/4 of the vertical length of the bottom portion 10c. The size of the stabilizer 12 is not limited to this size, but it is preferable to set it to the extent that rubble and the like are not easily caught. The stabilizing plate 12 contributes to stably holding the illustrated attitude of the shelter 1 . In the illustrated example, four stabilizers 12 are attached at equal angular intervals of 90° in the circumferential direction. This stabilizer 12 can also be attached to the bottom surface 10c of the third embodiment shown in FIG.

FIG. 6 illustrates a floating shelter according to the invention floating near the water surface S. FIG. Here, the shelter 1 of the first embodiment is shown as an example. The draft position of the shelter 1 is set substantially at the upper end position A of the body portion 10 . When a tsunami or flood occurs, a large amount of debris 60 exists in the water and randomly collides with the floating shelter 1 . Since the side surface 10a of the main body 10 located in the water has an inverted conical side surface 10a, the impact force when the rubble or the like 60 collides with the side surface tends to act upward on the shelter 1. .

FIG. 7 schematically shows a partial cross section including the side surface 10a of the main body 10, forces F1 to F4 of the same magnitude applied at various angles to the side surface 10a, and component forces thereof. Forces F1 to F4 are impact forces due to rubble or the like. For each of the forces F1 to F4, component forces in the direction perpendicular to the side surface 10a are indicated by symbols f1 to f4, respectively. A force component in the direction parallel to the side surface 10a does not act on the shelter 1 and is therefore not labeled. The components of force f1 to f4 in the direction perpendicular to the side surface 10a are forces substantially applied to the shelter 1, and all of them are diagonally upward forces. Therefore, since the shelter 1 is constantly subjected to a force directed toward the water surface S while being rubbed by the debris 60, the shelter 1 is less likely to sink into the water. Moreover, since the side surface of the main body part 10 is a smooth curved surface, debris or the like is less likely to be caught.

Such an action is the same for the shelters having reversed truncated cone-shaped sides in the second and third embodiments shown in FIGS. 2 to 5 and their variations. In addition, particularly in the embodiments shown in FIGS. 2 to 5, the characteristic shape of the bottom surface, that is, the upwardly convex curved surface, greatly contributes to imparting an upward force to the shelter 1 upon collision of rubble or the like 60. .

FIG. 8 is a schematic perspective view showing an example of a storage state when the floating shelter of the first embodiment is not in use. For example, the base 50 has a hole 51 for inserting and fixing the lower part of the main body 10 of the shelter 1 . Illustration of fixing means of the shelter 1 is omitted. Although not shown, for example, by providing stairs on the base 50, it is possible to easily get into the shelter 1 at the time of evacuation. Similarly, the floating shelters of the second and third embodiments can be stored using an appropriate base.

A specific example of the internal configuration of the floating shelter will be described with reference to FIGS. 9 and 10. FIG. FIG. 9 is a schematic vertical cross-sectional view showing a configuration example inside the internal space of the floating shelter of the first embodiment. FIG. 10 schematically shows the III-III section of FIG.

The internal space 40 of the body portion 10 (including the internal space of the canopy portion 20) can be partitioned into several levels as required. Moreover, a partition can also be provided as needed. A space directly entered from the hatch 11 is configured like a room having a floorboard 42 . A seat 41 such as a chair or a bench on which the evacuees X can sit is installed in the room. The empty space under the seat 41 can be used to store emergency supplies such as food, water, medicines and clothing. It is preferable to arrange communication equipment, lighting equipment, and the like as appropriate. Moreover, it is preferable to equip the body fixing means 46, such as a seatbelt, which each evacuee X wears. A ladder 43 for climbing from the room to the second hatch 21 of the canopy 20 is provided on the wall. The ventilation port 24 that can be opened and closed by a trigger valve or the like is attached to the canopy portion 20 in this example, but may be attached to the side wall of the main body portion 20 . Further, by providing a window 47 on the side wall of the main body 10, it is possible to confirm whether or not the shelter 1 is submerged in water. The window 47 is made of a strong transparent material such as a reinforced acrylic plate. If the evacuee can confirm that the shelter 1 is not underwater, the evacuee can decide to go outside without waiting for rescue.

A ballast 45 is mounted on the lower layer of the floor plate 42 . For example, ballast objects can be taken in and out through a door 42a formed in the floor plate 42 and leading to the lower layer. The appropriate weight of ballast 45 is adjusted according to the number of ballast individuals. If the number of evacuees who actually get on board is more than planned, the number of ballast individuals is reduced, and if the number is reduced, the number of ballast individuals is increased. For this reason, it is preferable to equip the base shown in FIG. 8 with a spare ballast piece for adjustment.

As an example, the size of the floating shelter 1 in FIG. 9 is about 15 m in length in the vertical direction, about 6 m in diameter at the upper end position A, about 2 m is about 1.8 m. In the case of the second and third embodiments shown in FIGS. 2 and 3, for example, the diameter at the upper end position A is approximately 6 m, and the diameter at the lower end position B is approximately 3.5 m. However, the size of the floating shelter is not limited to these dimensions.

FIG. 11 is a diagram schematically showing an example of a form in which the floating shelter 1 of the present invention is connected to a house for storage. The shelter 1 is installed, for example, on the base 50 shown in FIG. The base 50 is installed adjacent to the house 70 . Furthermore, a connecting passage 71 connecting one of the doorways of the house 70 and the hatch 11 of the shelter 1 is provided. In the illustrated example, one end of the connecting passage 71 is positioned at the window frame of the window on the second floor of the house 70 , and the other end of the connecting passage 71 is positioned around the hatch 11 . The connecting passage 71 can have, for example, a duct shape as shown or a bridge-like shape, and is supported at a predetermined position by an appropriate means (not shown). The connecting passage 71 and the floating shelter 1 are either loose or fixed by readily releasable means so that the shelter 1 can be immediately floated in an emergency. By getting used to going in and out of the shelter 1 from the house 70 on a daily basis, it is possible to immediately enter the shelter even in an emergency.

FIG. 12 is a diagram schematically showing an example of a form in which the floating shelter of the present invention is transported by vehicle. The floating shelter 1 can be easily transported by being mounted on a trailer vehicle 81 and towed by a suitable vehicle 80 . After reaching the destination, it is installed on the base 50 shown in FIG. 8 using a heavy machine such as a crane.

The floating shelter of the present invention described above is used, for example, as follows. After evacuees board from the hatch in the event of a tsunami, flood, or the like, when the volume of water around them increases, they begin to float due to buoyancy and are floated by water currents. Wait in the shelter until the weather conditions around you subside or the water recedes. The shelter has an inverted cone shape on the side or a curved bottom with an upward convex surface, so the impact force of debris etc. are also easily discovered. After the surrounding situation has subsided, open the upper second hatch and call for help using, for example, smoke flares and lights.

As a result, even if a house is about to be crushed by a debris flow, it is possible to enter the floating shelter in a few minutes and evacuate. can. Also, the number of missing persons can be reduced. The floating shelter of the present invention is small in size and easy to transport and move, so that it can be easily used even in ordinary households. It is suitable for people who cannot evacuate by car, especially the elderly.

Moreover, the embodiments illustrated and described here are examples, and the present invention is not limited to these, and various modifications are possible. In addition, when each component described in each embodiment can be applied to other embodiments, the present invention also includes a form in which they are applied.

1 shelter 10 main body 10a main body side faces 10b, 10c main body bottom 11 hatch 12 stabilizer 20 canopy 21 second hatch 22 hook 23 identification mark 24 ventilation valve 41 seat 42 floor plate 43 ladder 44 fixture 45 ballast 45a ballast individual 46 seat Belt 50 Installation base 60 Floating object 70 House 71 Connecting passage 80 Vehicle 81 Trailer vehicle A Main body upper end position B Main body lower end position C Central axis D Main body upper end diameter D1 Main body lower end diameter H Main body vertical length X Refugee w Stabilizer width h Stabilizer length

- An embodiment of the present invention is a floating shelter (1) for housing evacuees, comprising:
A main body (10) comprising a conical side surface (10a) whose diameter decreases from top to bottom, an internal space (40) for accommodating evacuees, and a hatch (11) for egress and egress of evacuees. When,
a canopy (20) covering the upper end opening of the main body (10);
a ballast (45) mounted within the interior space (40);
The ballast (45) is adjusted so that the draft position of the floating shelter (1) is substantially the upper end position (A) of the side surface (10a) of the main body (10) , and
The vertical length (H) from the upper end position (A) to the lower end position (B) of the side surface (10a) is 1.5 to 2.5 times the diameter (D) at the upper end position (A). There is .
- Another aspect of the invention is a floating shelter (1) for housing evacuees, comprising:
Equipped with a truncated conical or cylindrical side surface (10a) whose diameter decreases from top to bottom, an internal space (40) for accommodating evacuees, and a hatch (11) for egress and egress of evacuees. a main body (10);
a canopy (20) covering the upper end opening of the main body (10);
a ballast (45) mounted within the interior space (40);
The ballast (45) is adjusted so that the draft position of the floating shelter (1) is substantially the upper end position (A) of the side surface (10a) of the main body (10), and
The bottom surface (10b) of the main body (10) has an upward convex shape that gradually rises from the lower end position (B) of the side surface (10a) to the central axis (C) in a longitudinal section including the central axis (C). It is a surface of revolution obtained by rotating a curve around the central axis (C).
- Yet another aspect of the present invention is a floating shelter (1) for housing evacuees, comprising:
Equipped with a truncated conical or cylindrical side surface (10a) whose diameter decreases from top to bottom, an internal space (40) for accommodating evacuees, and a hatch (11) for egress and egress of evacuees. a main body (10);
a canopy (20) covering the upper end opening of the main body (10);
a ballast (45) mounted within the interior space (40);
The ballast (45) is adjusted so that the draft position of the floating shelter (1) is substantially the upper end position (A) of the side surface (10a) of the main body (10) ,
The bottom surface (10c) of the main body (10) has an upward convex shape that gradually descends from the lower end position (B) of the side surface (10a) to the central axis (C) in a longitudinal section including the central axis (C). A surface of revolution obtained by rotating a curve around the central axis (C) , and
The vertical length (H) from the upper end position (A) to the lower end position (B) of the side surface (10a) is 1.5 to 2.5 times the diameter (D) at the upper end position (A). There is .
- In the above aspect, a ventilation opening (24) provided in the main body (10) or the canopy (20);
It is preferable to further comprise a trigger valve provided for opening and closing the ventilation opening (24) and closing upon detection of vibration.

Claims (11)

A floating shelter (1) that accommodates evacuees and floats on the surface of the water,
A main body (10) comprising a conical side surface (10a) whose diameter decreases from top to bottom, an internal space (40) for accommodating evacuees, and a hatch (11) for egress and egress of evacuees. When,
a canopy (20) covering the upper end opening of the main body (10);
a ballast (45) mounted within the interior space (40);
A floating shelter, wherein the ballast (45) is adjusted such that the draft position of the floating shelter (1) is substantially the upper end position (A) of the side surface (10a) of the main body (10). A floating shelter (1) that accommodates evacuees and floats on the surface of the water,
Equipped with a truncated conical or cylindrical side surface (10a) whose diameter decreases from top to bottom, an internal space (40) for accommodating evacuees, and a hatch (11) for egress and egress of evacuees. a main body (10);
a canopy (20) covering the upper end opening of the main body (10);
a ballast (45) mounted within the interior space (40);
The ballast (45) is adjusted so that the draught position of the floating shelter (1) is substantially the upper end position (A) of the side surface (10a) of the main body (10), and
The bottom surface (10b) of the main body (10) has an upward convex shape that gradually rises from the lower end position (B) of the side surface (10a) to the central axis (C) in a longitudinal section including the central axis (C). A floating shelter, which is a surface of revolution obtained by rotating a curved line around the central axis (C). A floating shelter (1) that accommodates evacuees and floats on the surface of the water,
Equipped with a truncated conical or cylindrical side surface (10a) whose diameter decreases from top to bottom, an internal space (40) for accommodating evacuees, and a hatch (11) for egress and egress of evacuees. a main body (10);
a canopy (20) covering the upper end opening of the main body (10);
a ballast (45) mounted within the interior space (40);
The ballast (45) is adjusted so that the draught position of the floating shelter (1) is substantially the upper end position (A) of the side surface (10a) of the main body (10), and
The bottom surface (10c) of the main body (10) has an upward convex shape that gradually descends from the lower end position (B) of the side surface (10a) to the central axis (C) in a longitudinal section including the central axis (C). A floating shelter, which is a surface of revolution obtained by rotating a curved line around the central axis (C). A floating shelter according to claim 3, further comprising a plurality of stabilizing plates (12) projecting radially near the lower end of said bottom surface (10c). When the side surface (10a) has a truncated cone shape, the diameter (D1) at the lower end position (B) of the side surface (10a) is larger than half the diameter (D) at the upper end position (A). A floating shelter according to item 2 or 3. The vertical length (H) from the upper end position (A) to the lower end position (B) of the side surface (10a) is 1.5 to 2.5 times the diameter (D) at the upper end position (A). A floating shelter according to any one of claims 1 to 5, wherein a. Floating shelter according to any of the preceding claims, wherein the ballast (45) is composed of a multiplicity of ballast individuals. a ventilation opening (24) provided in the main body (10) or the canopy (20);
A floating shelter according to any preceding claim, further comprising a trigger valve provided for opening and closing the ventilation opening (24) and closing upon detection of vibration. Floating shelter according to any of claims 1 to 8, further comprising a hanging hook (22) attached to the surface of the canopy (20) for hanging the floating shelter (1) by heavy equipment. A floating shelter according to any preceding claim, further comprising an identification mark (23) attached to the surface of the canopy (20). Floating shelter according to any of the preceding claims, further comprising a second hatch (21) provided in the canopy (20).

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