JP6895042B2 - Memorial building and how to lay bones in this memorial building - Google Patents

Description

The present invention relates to the structure of a memorial structure such as a tomb, a mortuary, a mortuary, a monument, etc., which stores ashes, relics, souvenirs, lists, etc. inside.

Many of the memorial buildings have a storage room inside which stores ashes, relics, souvenirs, and lists. FIG. 14 is a schematic view showing a typical structure of a relatively large-scale tomb that stores the remains of, for example, 100 or more people, which is found in permanent memorial tombs. On the ground, a covered superstructure 1 having a space of about 1.8 m in length, 1.8 m in width, and 2.1 m in height, which allows people to enter, is on the floor 2. It is provided in. A flower stand 3 and an incense stand 4 are provided in front of the superstructure, and visitors usually worship here. Further, an entrance door 5 for entering the inside is provided on the back surface, and is used when storing and taking out the stored items. Below the floor 2, there is a foundation structure 7 made of concrete, and this foundation structure 7 is usually buried underground. Further, the center of the foundation structure 7 has a concave shape lower than the periphery.

FIG. 15 is a schematic view showing the internal structure of the superstructure 1 of the permanent memorial tomb shown in FIG. 14 (not shown). On the foundation structure 7, a floor 12 formed by arranging four floor stones 14 as shown in the figure is placed, and on the floor 12, a shelf 11 for storing a collection such as an urn is placed. Further, the floor 12 has a rectangular opening in a central portion thereof, a portion immediately above the concave shape in the center of the above-mentioned foundation structure 7. A floor hatch 13 is provided on the opening. Further, the shelves 11 are provided on three sides except the back surface of the superstructure 1 having a portion of the entrance door 5 (not shown).

16 to 18 are schematic views showing a BB cross section of FIG. 15, and show a typical structure of a storage room of a memorial building, and in this example, a bone burial room. The foundation structure 7 made of concrete is buried in the surrounding ground 18 so that its outermost surface is exposed to the ground surface, and the central portion thereof is recessed with respect to the outer peripheral portion, and this recess is a bone-bearing chamber for storing the ashes. It is 19. The side surface and bottom surface of the bone burial chamber 19 are formed of concrete integrally with the foundation structure 7. A floor stone 14 made of granite is adhered on the foundation structure 7 by a mortar or the like (not shown), but an opening is provided in a portion corresponding to the top surface of the bone burial chamber 19. A floor hatch 13 is placed on the opening. Normally, the shelf 11 stores a plurality of urns containing the ashes of one body, whereas the urn chamber 19 stores the ashes of a plurality of bodies in a mixed state.

17 and 18 are modified examples of the structure shown in FIG. 16, FIG. 17 shows a case where an opening 39 penetrating the ground 18 is provided on the side surface and the bottom surface of the bone burial chamber 19, and FIG. 18 shows a case where the bone burial chamber 19 is provided. The case where the ground 18 is exposed without providing the concrete wall surface on the bottom surface of the above is shown respectively.

By the way, many of the storage rooms of memorial buildings are located outdoors or underground, and the pollution of the storage due to the ingress of water has been a problem. In addition, odors caused by mold and dead microorganisms that have propagated may be generated from the collections soaked in water. Since the collection represented by the remains is an object of reverence for visitors to the monument, the generation of stains and odors greatly damages the emotions of such visitors. In particular, when a new collection is put in or taken out, the door of the storage place is opened, so the condition of the collection is visually observed and the odor is also noticeable. Even bigger.

The infiltration of water into the bone burial chamber 19 shown in FIG. 16 occurs from cracks formed on the side surfaces and bottom surfaces of the bone burial chamber 19 from the surrounding ground 18 and also permeates through the members such as concrete constituting the bone burial chamber 19. The infiltrated water pollutes the ashes and other stored items, and also causes the growth of mold and microorganisms. The structure in which the bottom surface of FIG. 18 is not covered with concrete generally has a low risk of water entering through the ground, and when there is a concern about water leaking mainly from the superstructure, the water that has entered is discharged as soon as possible. It is used when it is intended that the ashes will not be submerged in water for a long period of time by being discharged into the ground. In an environment where the ingress of water through the ground is dominant, the bottom surface as shown in FIG. 16 is also covered with a solid member. The structure that takes an intermediate measure between the two is shown in FIG.

In FIG. 16, the bone burial chamber 19 is buried in the ground 18, but a part of the bone burial chamber 19 may be exposed to the ground surface. Even in that case, the above-mentioned infiltration of water and the problems associated therewith occur.

FIG. 20 is a schematic view showing a typical structure of a tomb, which is another example of a memorial building. The tomb consists of a superstructure 21 made by laminating a plurality of stones, including a member called a pole stone engraved with the name of a house or the name of a deceased person, and a turf stand 41 that is in contact with the lower part of the structure 21. , The ossuary chamber 29 which is the lower part thereof is provided. The bone burial chamber 29 may be provided on the ground, or when only the superstructure 21 and the turf stand 41 are provided on the ground and the bone burial chamber 29 is provided underground, or in between the two, a part of the bone burial chamber. In some cases, it is installed underground. When the bone burial chamber 29 is provided on the ground, it is generally not necessary to assume the intrusion of water from the surrounding ground, but when at least a part of it is buried in the ground, it is shown in FIG. As with the relatively large tombs, the above-mentioned infiltration of water and the associated challenges arise.

In order to deal with the problems described in detail above, the techniques shown in FIGS. 21 and 22 have been conventionally proposed as measures to prevent the collection from coming into contact with the water even if water enters the bone burial chamber. Has been done. FIG. 21 is a schematic view showing a bone tray 43 with a ceramic float to be housed in the storage chamber, and the bone tray is composed of a ceramic float 44 and a wire mesh 45 provided on the ceramic float 44. FIG. 22 shows a schematic cross-sectional view showing a state in which the bone tray 43 with a ceramic float is housed in the bone burial chamber 42. By using the bone tray 43 with a ceramic float, even if water collects in the bone burial chamber 42, the ashes will not be flooded. Such a technique is disclosed in Patent Document 1 (Utility Model Registration No. 3098452).

Further, in order to deal with the above-mentioned problems, Patent Document 2 (Patent No. 6465491) has been reported as a measure to prevent water from entering the bone burial chamber. In this document, the bone chamber is formed by processing a block of stone. By doing so, since there is no connection in the bone burial chamber, it is possible to prevent the ingress of water even in the event of an earthquake or aged use.

Utility Model Registration No. 3098452 Japanese Patent No. 6465491

However, the technique of Patent Document 1 has the following problems. If a container for storing the ashes is provided above the float so that the container always floats on the surface of the water, it is possible to prevent the ashes from being submerged in water, but in that case, of course, there should be a place to store the ashes under the surface of the water. It cannot be provided. That is, even if the bone-feeding chamber is provided, the portion below the height assumed as the water level of the infiltrated water cannot be substantially used as the bone-feeding space. For example, in the case of a relatively large tomb such as the permanent memorial tomb shown in FIG. 14, the underground bone-laying space often requires a depth of 1 m or more. That is, if the capacity of the bone storage space cannot be secured in the depth direction and a large amount of ashes cannot be stored, it is often impossible to satisfy the construction and maintenance costs with the consideration associated with the storage of the ashes. This is because if the bone-laying space is expanded in the horizontal direction, it is necessary to increase the size of the entire building, which greatly increases the construction cost and the building area. However, if it is necessary to build a tomb with a depth of 1.5 m in a low-lying wetland in a heavy rain area, for example, in a place where groundwater can already be seen when digging 30 cm from the ground surface immediately after rainfall, the patent document With the technology presented in 1, it is not possible to construct a permanent memorial tomb that can be practically managed and maintained.

On the other hand, the technique of Patent Document 2 has the following problems. For example, it is assumed that the tomb having the bone burial chamber 19 shown in FIG. 16 described above is erected in a place where groundwater can already be seen when digging 30 cm immediately after rainfall. Further, the bone burial chamber 19 is formed by processing a mass of stone material, and it is assumed that water does not enter the chamber. Then, buoyancy is generated in the portion of the bone burial chamber 19 that is lower than the groundwater level. Due to this buoyancy, a vertically upward stress is generated in the bone burial chamber 19 to push up the foundation structure 7. On the other hand, since the superstructure (not shown) generates vertical downward stress in the foundation structure 7 due to its weight, as a result, shear stress is applied to the portion where the bone burial chamber 19 and the foundation structure 7 are connected. Often this shear stress results in the formation of cracks 40 at the connection, as shown in FIG. Of course, it is possible to prevent the occurrence of cracks to some extent by designing the structure in consideration of the shear stress in advance, but for that purpose, a more robust structure is required compared to the case where buoyancy does not need to be considered. It costs extra because it is needed. Further, even if a robust structure that does not generate cracks is secured, there is a risk that the entire structure will be tilted due to the moment caused by the interaction between the buoyancy and the stress caused by the weight of the superstructure.

That is, the memorial building according to claim 1 is
At least part of it is buried underground, and there is a bone burial chamber where water can enter from the surrounding ground.
It is equipped with a bottomed container placed in the bone-feeding chamber.
The container, when entering the water in the burial chamber, even submerged a part of water, the interior has a structure in which water does not enter immersion, and so that it can be floated and down in the vertical direction It is characterized by not being fixed to the outside of the container.

In addition to the requirements described in claim 1, the memorial building according to claim 2 is added to the requirements described in claim 1.
The outer shell of the container, which is exposed to water, is characterized in that it is made of stainless steel.

In addition, the memorial building according to claim 3 is in addition to the requirements according to claim 1 or 2.
The inner wall of the container is characterized by being formed of a material having corrosion resistance to an acidic solution, particularly an aqueous solution containing at least one of citric acid, glacial acetic acid, and lactic acid.

In addition, the memorial building according to claim 4 is in addition to the requirements according to any one of claims 1 to 3.
It further includes a structure that is placed or fixed in the container, and the structure is characterized in that it is arranged integrally with the container so that it can ascend and descend in the vertical direction. Is.

In addition, the memorial building according to claim 5 is in addition to the requirements according to claim 4.
When the container and the structure are fixed to each other, they are fixed by a method that can be reversibly separated and combined.

In addition, the memorial building according to claim 6 is in addition to the requirements according to any one of claims 1 to 4.
Further comprising a structure which is spaced directly above of the container, and the structure is arranged so that it can be further floating vertically the container becomes the container and integrally at the time of the floating distance between the release It is characterized by being done.

In addition, the memorial building according to claim 7 is in addition to the requirements according to any one of claims 4 to 6.
Each container is characterized by containing one or more of the above-mentioned structures as an integral body in a state where it can be separated into two or more pieces or two or more pieces.

In addition, the memorial building according to claim 8 is in addition to the requirements according to any one of claims 1 to 3.
The lower end of the placed the container in the burial chamber, if the basement depth exceeds 80cm from the ground surface, weight of the container: the M [kg], from the ground surface of the container The volume of the portion of 80 cm or less: V [m ³ ] is characterized by satisfying the following relationship.
M ≧ 1.01 × V × 1000

In addition, the memorial building according to claim 9 is in addition to the requirements according to claim 4 or 5.
When the lower end of the container on which the structure is placed or fixed is underground at a depth of more than 80 cm from the ground surface, the total weight of the container including the structure : M [kg] and the volume. The volume of the portion 80 cm or less from the ^{ground surface of the container: V [m 3} ] is characterized by satisfying the following relationship.
M ≧ 1.01 × V × 1000

In addition, the memorial building according to claim 10 is in addition to the requirements according to claim 9.
If the structure is, Ru is arranged so that the container is the container and integrally at the time of the distance g [cm] flying, the total weight of the container containing the structures: and M (kg), the land of the container The volume of the portion (80 + g) cm or less from the upper surface: V [m ³ ] is characterized by satisfying the following relationship.
M ≧ 1.01 × V × 1000

In addition, the memorial building according to claim 11 is in addition to the requirements according to any one of claims 1 to 10.
It is characterized in that at least one opening is provided on the side surface or the bottom surface of the bone burial chamber.

In addition to the requirements described in claim 11 , the memorial building according to claim 12 has the requirements described in claim 11.
It is characterized by arranging at least one of crushed stone or porous concrete on the outside of the opening.

In addition, the memorial building according to claim 13 is in addition to the requirements according to any one of claims 1 to 12.
In a state where the container has landed on the ground without rising in the bone-feeding chamber, the lower end of the container and the bottom of the storage chamber are not in close contact with each other, and at least a part of the container is separated to form a gap. It is characterized by.

In addition, the memorial building according to claim 14 is in addition to the requirements according to any one of claims 1 to 13.
It is characterized in that an O-ring is arranged between the container and the wall surface of the bone burial chamber in which the container is housed.

In addition, the memorial building according to claim 15 is in addition to the requirements according to claim 14.
The O-rings are characterized in that they are arranged at two or more locations apart from each other in the vertical direction.

In addition, the memorial building according to claim 16 is in addition to the requirements according to any one of claims 1 to 15.
The container is characterized in that it is composed of a plurality of parts or a plurality of parts integrated by means that can be separated from each other.

The bone-laying method according to claim 17 is characterized in that the burnt bone is placed in the commemorative building according to any one of claims 1 to 16.

According to the present invention, even if water infiltrates into the bone burial chamber, the stored matter in the bottomed container placed inside the ossuary chamber is the water even if it is under the surface of the infiltrated water. It will not be soiled or give off an odor. In addition, since the groundwater in the surrounding ground is infiltrated into the bone burial chamber, the stress caused by the buoyancy caused by the groundwater does not cause damage or inclination of the memorial building such as cracks.

It is a perspective view which shows the 1st Embodiment of this invention. It is sectional drawing which shows the 1st Embodiment of this invention. It is sectional drawing which shows the 1st Embodiment of this invention. It is sectional drawing which shows the 1st Embodiment of this invention. It is sectional drawing which shows the 2nd Embodiment of this invention. It is sectional drawing which shows the 3rd Embodiment of this invention. It is sectional drawing which shows the 4th Embodiment of this invention. It is sectional drawing which shows the 5th Embodiment of this invention. It is sectional drawing which shows the 6th Embodiment of this invention. It is sectional drawing which shows the 7th Embodiment of this invention. It is sectional drawing which shows the 8th Embodiment of this invention. It is sectional drawing which shows the 9th Embodiment of this invention. It is sectional drawing which shows the tenth embodiment of this invention. It is a perspective view which shows the appearance of a relatively large-scale tomb seen in a permanent memorial tomb. It is a perspective view which shows the internal structure of a relatively large-scale tomb seen in a conventional permanent memorial tomb. It is sectional drawing which shows the internal structure of the conventional bone burial chamber. It is sectional drawing which shows the internal structure of the conventional bone burial chamber. It is sectional drawing which shows the internal structure of the conventional bone burial chamber. It is sectional drawing which shows the internal structure of the conventional bone burial chamber. It is a schematic diagram which shows the typical structure of a tomb. It is a schematic diagram which shows the structure of Patent Document 1. It is a schematic diagram which shows the structure of Patent Document 1.

Hereinafter, the internal structure according to the embodiment of the present invention will be described by taking the tomb having the appearance shown in FIG. 14 as an example.

FIG. 1 is a perspective view showing the first embodiment of the present invention, and is a schematic view showing the internal structure of the superstructure 1 of the permanent memorial tomb shown in FIG. 14 (not shown). A floor 102 is placed on the foundation structure 107 having a recess in the center, and a shelf 101 on which a collection such as an urn is placed is placed on the floor 102. Further, as for the floor 102, four first floor stones 104 and a second floor stone 105 having a rectangular opening in the central portion thereof directly above the recess of the foundation structure 107 are arranged as shown in the figure. Further, it is configured by providing a floor hatch 103 on the opening. The first floor stone 104 and the second floor stone 105 are granite, and the floor hatch 103 is made of stainless steel. Further, the shelves 101 are provided on three sides except the back surface of the superstructure 1 having a portion of the entrance door 5 (not shown). The size of the floor 102 and the portion of the foundation structure 107 on which the floor 102 is placed is 2.2 m both vertically and horizontally.

FIG. 2 is a schematic view showing a cross section taken along the line AA of FIG. 1 and shows the structure of the ostomy chamber. The foundation structure 107 made of concrete is buried in the surrounding ground 108 so that its outermost surface is exposed to the ground surface, and the central portion thereof is recessed with respect to the outer peripheral portion, and this recess is a bone burial that stores the ashes. It is a room 109. More specifically, the foundation structure 107 is lowered in three stages from the outer peripheral portion to the central portion, and has a first bottom surface 1071, a second bottom surface 1072, and a third bottom surface 1073 as shown in the figure. doing. The third bottom surface 1073 is the bottom surface of the bone burial chamber 109. The side surface and bottom surface of the bone burial chamber 109 are made of concrete integrally with the foundation structure 107. A first floor stone 104 made of granite is adhered on the foundation structure 107 by a mortar or the like (not shown). Inside the first floor stone 104, a second floor stone 105, also made of granite, is placed as shown in the figure. The second floor stone 105 is not adhered to the foundation structure 107, and is placed on the first bottom surface 1071 of the foundation structure 107 as shown in the drawing. A container 106, which is one size smaller than the bone burial chamber, is placed on the third bottom surface 1073. The container 106 is a bottomed container which is made by welding a plate made of stainless steel SUS304 to be watertight and has an opening for loading the stored items. At the upper end of the container 106, an overhang 110 is provided so as to have a horizontal plane. The overhang 110 is arranged as shown so as to fit in the gap formed between the second floor stone 105 and the second bottom surface 1072 of the foundation structure 107. That is, the container 106 is only placed on the third bottom surface 1073 and is not fixed to the outside. The dimensions around the ostomy chamber 109 shown in FIG. 2 are shown in FIG. The width Wc of the bone burial chamber 109 is 0.8 m, and the depth in the vertical direction with the paper surface is also 0.8 m. The distance Lc from the third bottom surface 1073 to the ground surface is 1.08 m. The width Wt of the container 106 placed in the bone-feeding chamber is 0.78 m, the depth in the vertical direction with the paper surface is 0.78 m, and the height Lt is 1.0 m. The thickness t of the stainless steel constituting the container 106 is 1 cm. The mass of the container 106 manufactured to such a size was 289 kg. The distance g from the upper end of the container 106 to the second floor stone 105 is 1 cm. Further, FIG. 3 shows the water 111 that has infiltrated from the surrounding ground 108 through the foundation structure 107, and the distance from the third bottom surface 1073 to the water surface of the water 111 is Lw. The width W1 of the second floor stone 105 is 1 m, the depth of the paper surface and the vertical direction is 1 m, the width W2 of the rectangular opening in the center thereof is 0.7 m, the depth of the paper surface and the vertical direction is 0.7 m, and the thickness. It is assumed that d1 is 0.1 m and the mass is 132.6 kg. Further, the mass of the floor hatch 103 placed on the second floor stone 105 is 5 kg, and the height d2 from the second floor stone 105 is 0.04 m.

Here, the behavior of the container 106 will be described on the assumption that water gradually infiltrates into the bone burial chamber 109 from the surrounding ground. Buoyancy is generated in the container 106 by the water 111 shown in FIG. Its size is easy based on Archimedes' principle that "an object that is completely or partially submerged in a fluid is pushed vertically upward from the fluid with a force equal to the weight of the excluded fluid." Can be asked for. Now, the specific gravity of the water 111 is set to 1.01, and the Lw when a buoyancy that is just balanced with the mass of the container 106 of 289 kg is generated is obtained. That is, the volume of water having a mass of 289 kg excluded by the container 106 is 0.286 m3 when the specific gravity is 1.01, so the depth of the portion where the container of 0.78 m in length and width is immersed in water is 0. It is required to be .47m. Therefore, if Lw ≦ 0.47 m, the container 106 does not float and lands on the third bottom surface 1073. When LW> 0.47 m, the container 106 floats, and when Lw reaches 0.48 m, the upper end thereof contacts the second floor stone 105. As the Lw increases further, the container 106 contacts the second floor stone 105 until a buoyancy is generated that balances the total mass of the container 106, the second floor stone 105, and the floor hatch 103, which is 426.6 kg. Maintain the position when it was done. By performing the same calculation, it can be seen that when Lw exceeds 0.70 m, the container 106 starts to ascend in the vertical direction again together with the second floor stone 105 and the floor hatch 103. Finally, as an assumption of the maximum amount of water invading the bone burial chamber in the permanent memorial tomb according to the present embodiment, assuming that the water surface reaches a height corresponding to the ground surface, the state of the container 106 in that case is shown in FIG. Shown in. At this time, the distance d3 from the ground surface to the top surface of the floor hatch 103 is derived as d3 = Lt + d1 + d2- (0.70-g), and is 0.45 m. That is, in the permanent memorial tomb according to the present embodiment, even if the container 106, the second floor stone 105, and the floor hatch 103 rise vertically to 0.45 m from the ground surface, they do not interfere with the shelf 101. Even if the groundwater level rises to the ground surface, the container 106 floats in the vertical direction, so that it is the only upper part of the container that can be a path for water to enter. The opening is not submerged, and therefore the ashes and the like contained therein are not submerged in water, including those below the water surface of the water 111. Further, since water has infiltrated into the bone burial chamber 109 from the surrounding ground 108, buoyancy is not generated, and there is no possibility that the foundation structure 107 will be cracked or tilted due to shear stress. .. When the water that has entered the bone burial chamber 109 gradually drains from the state shown in FIG. 4, the container 106 and the second floor stone 105 and the floor hatch 103 placed on the container 106 are reduced as the Lw decreases. However, it will descend in the vertical direction as a unit.

One year has passed since the ashes were stored in the bone burial chamber 109 of the permanent memorial tomb of this embodiment, and then the floor hatch 103 was released for new bone laying, but the ashes that had already been stored were not found to be soiled. Also, no odor was felt. A bone-feeding worker who has abundant experience in delivering bones to the bone-feeding room of a conventional permanent memorial tomb is caused by the stain and odor of the bone-feeding place, which he felt in the conventional bone-feeding work in the clean bone-feeding work according to the present invention. The work was done in a state of being free from the mental stress and the accompanying increase in blood pressure and sweating. In addition, the owner of the ashes who was watching over the work did not express any grief or dissatisfaction caused by the stain or odor of the bone-feeding place, as was heard in the conventional bone-laying work.

As described in detail above, in the permanent memorial tomb of the present invention, the size and mass of the container placed in the bone burial chamber, the mass of the structure that rises and falls in the vertical direction together with the container, and the invasion into the bone burial chamber. From the relationship between the specific gravity of the water and the assumed maximum water level, the maximum amount of rise of the container derived by Archimedes' principle is derived, and even if the derived maximum amount of rise is made, the container does not interfere with other components. By arranging it in, it is possible to prevent the above-mentioned problems from occurring. Therefore, if this condition can be satisfied, it is not always necessary to depend on the size, shape, and arrangement of various members in the present embodiment.

For example, by increasing the mass of the container and the member that rises integrally with the container, the container may be designed so that the container does not rise at all even if water infiltrates to the assumed maximum water level in the bone burial chamber. The smaller the assumed amount of rise, the more effectively the space directly above the container can be used. However, on the other hand, since a weight equal to or greater than the maximum buoyancy to be received is required for the container and the member that rises in the vertical direction integrally with the container, the container that can withstand the weight and the strength of the bone burial chamber are required.

Further, if the mass of the container itself can be suppressed to a desired amount of rise, a structure that rises and falls in the vertical direction integrally with the container, such as the second floor stone 105 and the floor hatch 103 in the present embodiment. It does not have to be. In addition, when a structure that rises and falls in the vertical direction is provided integrally with the container, even if it is not a second floor stone or floor hatch, or a decorative item such as a Buddha statue, it is a cast iron weight or sand. May be good. Further, the installation location may not be the upper part of the container as in the present embodiment, but may be a method such as storing the container inside the storage container. Further, the second floor stone 105 and the floor hatch 103 in the present embodiment were arranged so as to be placed on the container 106 when the container 106 was raised by the distance g in FIG. 3, but the container 106 was the third. It may be arranged so as to be placed on the container 106 in a state of being landed on the bottom surface 1073 of the above, and may be fixed not only on the container 106 but also on the container 106. Needless to say. However, in the steady state, the second is in the steady state, except in the non-steady state when the container is rising more than usual as a result of more water infiltrating from the surrounding ground into the bone burial chamber due to the influence of heavy rain. It is more desirable that the floor stone 105 and the floor hatch 103 are not placed on the container 106 and have some gaps as shown by the distance g in FIG. By avoiding the arrangement in which the second floor stone 105 and the floor hatch 103 are always placed on the container 106, the load of the second floor stone 105 and the floor hatch 103 is constantly applied to the container 106, and the container 106 is moved. This is because it is possible to avoid the risk of stress corrosion cracking at the welded portion of the constituent stainless steel plate and defects such as plastic deformation of the container itself.

The floor hatch 103 is provided to prevent small animals and the like from entering the bone burial chamber 109 and to prevent the occupants from falling. However, a part of the hatch is made of wire mesh to ventilate the floor hatch 103. It is desirable to ensure sex. This is because if the air permeability is not ensured, if the water 111 shown in FIG. 3 is vaporized, there is a risk that dew condensation will form on the lower surface of the floor hatch 103 and fall into the container 106 to wet the stored items with water.

Further, in the design described in the present embodiment, the mass of the stored material contained in the container 106 was not taken into consideration. In the case of the permanent memorial tomb illustrated in the present embodiment, it should be assumed that the amount of burnt bone to be stored in the container 106 is small and is almost ignored in the calculation of the amount of rise of the container, such as immediately after the start of use. This is because the design is such that the container does not interfere with the shelf 101 even if the container rises by the maximum amount in the state where there is no storage. Needless to say, if the weight of the collection can be estimated at the design stage, it can be taken into consideration when calculating the amount of increase. In addition, it is necessary to pay attention to the maximum mass of the stored items to be stored in the container. It is assumed that the water level of the water that has entered the bone burial chamber 109 is the highest in the state where the maximum mass of the stored material is stored in the container 106. As a result of the storage of the maximum mass being stored, the weight is such that the container does not float even if the opening for loading the storage provided above the container is submerged, and the water level in the bone storage chamber 109 exceeds the opening. This is because the inside of the storage container will be flooded. If a door is provided at the opening of the container and the door has a watertight structure, water can be prevented from entering even if the opening is flooded, but in the case of storing the collection for a considerable period of time like a memorial building. In reality, it is very difficult to realize a structure that maintains watertightness for a long period of time, and to take out the collection regularly and check the watertightness of the container. In order to prevent such a situation, even if the maximum mass of the storage is stored, the container is designed so that the container floats before it is flooded to the opening for loading the storage provided above the container, or the bone storage chamber. Even if the container does not float when the water level of the water that has entered the 109 is the highest, it is necessary to design the opening so that it is above the water surface. If it is difficult to estimate the maximum water level of the water that enters the bone burial chamber 109, it is certain that the opening is arranged above the ground surface even when the container does not float.

Further, in the present embodiment, the width Wt of the container 106 placed in the bone-feeding chamber is set to be 2 cm smaller than the width Wc of the bone-feeding chamber 109, but it goes without saying that this Wc-Wt does not have to be 2 cm. No. However, if Wc-Wt is taken too large, the container tends to tilt in the bone burial chamber when the container rises due to buoyancy, and if it is taken too small, it is affected by variations in Wc and Wt locations. There is a risk of interference between the bone burial chamber and the container. Therefore, it is more desirable to design Wc-Wt within 0.5 cm or more and 6 cm or less.

Further, in the present embodiment, an overhang 110 is provided at the upper end of the container 106 so as to have a horizontal plane. The overhang has the effect of suppressing the plastic deformation of the upper end of the container by increasing the contact area when the container rises due to buoyancy and comes into contact with the second floor stone 105. There is no effect on the purpose of.

Further, in the present embodiment, the container 106 is made of SUS304. SUS304 is a material particularly suitable for the container of the present invention because it has excellent durability, strength, and relatively low cost even in an environment exposed to water. However, even in stainless steel other than SUS304, for example, to an FRP resin, it may not be stainless steel as long as the material prevents immersion entering the water (passing).

In the memorial building of the present invention, it is necessary to design the structure assuming the specific gravity and the maximum water level of the water entering the bone burial chamber as described above. The water level is assumed to be the state where the underground water level is located at a distance of several centimeters from the surface of the earth, but in order to make this estimation precisely, the underground water level at the construction site must be measured for a considerable period of time. Need to be done. This is because the underground water level is not uniform due to the influence of the weather, the pumping condition of groundwater in the surrounding area, and the ebb and flow of the tide near the coast. However, it is often difficult to carry out such a detailed preliminary survey in the construction of a memorial building from the viewpoint of economic rationality. However, as a result of scrutinizing the inundation situation of many underground storages in Japan, the inventor found that the distance from the ground surface to the water surface is as high as 80 cm at the shortest, except during non-stationary times such as when affected by heavy rain. By the way, I found for the first time that water was generated in the underground storage.

In general, the purpose of a person visiting a memorial building is to obtain spiritual well-being through acts such as worship while visiting the building and looking at its appearance. Therefore, a certain degree of aesthetics is required for the part that is visible to the visitor. In this regard, in the memorial building of the present invention, when the container and the member that ascends and descends integrally with the container are normally buoyant and ascend, it is witnessed that a minute vertical movement is repeated. In addition, it is not preferable because the side surface of the outer wall of the container, which is contaminated when submerged in water, may get in the eyes. Furthermore, if the container and a part of the member that rises and falls integrally with the container also serve as the floor surface for a tour, worship, or work place, there is a risk that a person may get on the raised part and get injured. For this reason, in the steady state, the storage container should be kept at the lower limit in the vertical direction in the storage, and the storage container should rise only in an emergency such as after heavy rain to protect the stored items from submersion. There is a certain rationality in designing.

For this reason, it is difficult to estimate the groundwater level, and the lower end of the container placed in the storage chamber and the structure placed or fixed in the container exceeds 80 cm from the ground surface. In the case of being underground at a depth, as a design guideline, the part of the structure that rises and falls in the vertical direction together with the container and the container is at a depth of more than 80 cm from the ground surface. A state in which a container and a structure that is placed or fixed in the container and rises and falls in the vertical direction together with the container are deferred to the lower limit in the vertical direction even in water. I got a rational design guideline to design so that it does not come up from the container. However, as in the present embodiment shown in FIG. 3, when the container 106 is placed under the second floor stone 105 at a distance g by a distance g when the container 106 is left at the lower limit in the vertical direction, it floats in a steady state. It is desirable not to do this because it is not the container 106 but the second floor stone 105 placed on it, so the container 106 itself is when the part at a depth of more than 80 cm from the ground surface is in the water. , Only the distance corresponding to the distance g may be levitated from the state of being deferred to the lower limit in the vertical direction. This guideline can be expressed by Archimedes' principle as shown in equation (A).
M ≧ 1.01 × V × 1000 … (A)
However, M is the total weight [kg] of the container and the structure placed or fixed in the container, and V is placed in the bone burial chamber as a unit of the container and the structure. In the case, it is the volume [m ³ ] of the portion deeper than 80 cm from the ground surface of the one piece. In addition, the container and at least a part of the structure are placed in the bone burial chamber apart from each other in the vertical direction, and when the container floats g centimeters, the container comes into contact with the structure. If so, M is the total weight of the structure, the container, and the structure placed or fixed in the container: M [kg], and V is (80 + g) from the ground surface of the container. The volume [m ³ ] of the part deeper than the centimeter. Further, 1.01 in the formula is a number assuming the specific gravity of water. Since it is assumed that salt and the like are dissolved in groundwater, it is preferable to estimate it with 1.01 because it has a slightly higher specific density than fresh water. In terms of satisfying this equation, M has a desired characteristic, but it should be noted that the heavier the weight of the container or structure, the more the strength of the container itself or the ostomy chamber needs to be increased.

Based on this point, a more desirable design guideline is 1.01 × V × 1.3 × 1000 ≧ M ≧ 1.01 × V × 1000 … (B).
Will be. That is, by designing M so as to be between 1.01 × V and a weight 30% heavier than that, the above guideline does not incur unnecessary costs for ensuring the strength of the container itself and the bone burial chamber. You can get a memorial building along the line. Even if the design satisfies the formula (A) or (B), the distance from the ground surface to the water surface may be less than 80 cm in the unsteady state, so it is assumed that the container floats in that case. In this case, it goes without saying that it is necessary to prevent the arrangement of the container and the structure vertically above the container from interfering with each other as described with reference to FIG. If it is assumed that the container will not float, it is necessary to design the opening provided in the container so that it is always above the water surface. This design guideline is intended to be used when it is difficult to estimate the underground water level, so if the container is designed so that it does not float, the opening provided in the container is practically even the ground. It is desirable to arrange it so that it is located above the ground surface so that it will not be flooded even if the underground water level rises to the surface.

Next, another effect that is particularly effective when the present invention is used for a burial mound for storing ashes will be described. Generally, the skeleton room of a burial mound stores a large number of human bones, for example, about several hundred people. However, while it takes several hundred years for the human bones stored in the bone burial chamber to be decomposed, for example, it takes only a few years to store the remains of hundreds of people depending on the usage pattern. In some cases. In such a case, the amount of new human bones that are overwhelmingly stored is larger than the amount of human bones that are decomposed, so the bone burial chamber is filled with ashes, and sooner or later, the capacity to store new ashes will be exhausted. To do. Therefore, a technique is known in which an acidic solution is added to the ashes on a regular basis and dissolved in several years. Specifically, it is a technique for periodically spraying an aqueous solution containing at least one of citric acid, glacial acetic acid, and lactic acid. In case burial grave according to the invention is the way, the remains are being collection in the container without immersion entry of water from the outside (passage) is, that the container leaving the natural that the solution charged into the inside while the outside Absent. Therefore, it is also suitable as a reaction vessel in which the above-mentioned aqueous solution is put into the vessel to cause dissolution of the stored ashes. The liquid charged by the reaction becomes an aqueous solution of the calcium compound derived from the ashes. Since the container of the present invention has no means of actively discharging the solution to the outside, the water naturally evaporates and the once dissolved calcium compound is repeatedly precipitated. However, from the state where ashes of various sizes and shapes are piled up while creating voids, a large volume reduction will occur in the process of once melting and recrystallization, so a capacity to store new ashes is secured. You will be able to do it. By the way, for the dissolution reaction of the ashes by this acidic solution, the state where the ashes are covered with mud or impregnated with groundwater becomes a reaction inhibitory factor. Therefore, as described above, the tomb of the present invention in which the stored ashes are not contaminated by the groundwater derived from the surrounding ground is also suitable for reducing the volume of the ashes by the acidic solution. However, in carrying out this reaction, the ashes storage container must be resistant to an aqueous solution containing at least one of citric acid, glacial acetic acid, and lactic acid. For example, the outer shell, which is exposed to water, is made of SUS304 to ensure strength, and a container made of acid-resistant resin such as polyethylene or fluororesin is placed inside the container to form a double-structured container. By coating the inner wall of the SUS304 container with zirconia or titanium, both the strength of the container and the acid resistance can be achieved. Of course, even in a method such as making the container itself into earthenware, it is sufficient that the inner wall of the container is made of a material having corrosion resistance to an aqueous solution containing an acidic solution, particularly citric acid, glacial acetic acid, and lactic acid.

Next, another effect brought about by the present invention will be described. Generally, memorial buildings are expected to survive for at least several decades. In particular, in the case of a permanent memorial tomb as described in the present embodiment, it is literally provided for a permanent memorial service. However, while using these memorial buildings for a long period of time, due to the effects of natural disasters such as earthquakes and deterioration over time, repair and rebuilding work is required, and in that case it is necessary to temporarily take out the collection. It is expected to occur. Generally, the bone burial chamber of a burial mound is relatively narrow and deep as mentioned in this embodiment, and it is not assumed that a person enters the inside and takes out the collection. In the first place, working with your feet on the ashes that have been put in is a strong repulsive feeling not only for the worker himself but also for the worshipers. It is also very difficult to completely recover the partially powdered burnt bone. However, if the container according to the present invention is placed in the bone burial chamber and the ashes are stored in the container, the whole container can be taken out, so that not only the work is extremely easy, but also the foot is put down on the ashes. There is no need, and even finer ashes will not remain uncollectible. However, when taking out the container, it is necessary to design in consideration of its weight in advance. For example, the container 106 used in the present embodiment was made of SUS304 having a thickness t of 1 cm and having a mass of 289 kg, as described above. Since it is very difficult and dangerous to manually lift a container of this weight and move it to another place, a hook is provided in advance on the container so that it can be caught by a winch or the like with a wire so that it can be moved. In order to reduce the weight by making the thickness t thinner within the range allowed by the strength and to suppress the rise when buoyancy is generated, in the vertical direction integrally with the container, such as the second floor stone 105 and the floor hatch 103 in the present embodiment. When making the ascending / descending member heavier and taking out the container, it is desirable to reduce the weight of the structure to be handled at one time by first taking out the member prior to the container. Further, in the latter case, and when the container and the member that rises and falls in the vertical direction integrally with the container are fixed to each other, the member is removed before taking out the container, and the container is removed. Needless to say, the container and the member must be fixed by a method that can be reversibly separated and combined, such as bolting or clamp fixing, so that the member can be attached again after being put back in place. No.

FIG. 5 shows a second embodiment of the present invention, and like FIG. 2, is a schematic view showing a cross section taken along the line AA of FIG. 1 and shows the structure of a bone burial chamber. However, the shelf 101 shown in FIG. 2 is not drawn. The difference from the embodiment shown in FIG. 2 is that the portion of the second floor stone 105 in FIG. 2 has been changed to the second floor stone 205 and the weight 212. The shape of the weight 212 as seen from the upper surface is represented by a "square" shape like the second floor stone 205, and as shown in the figure, the weight 212 has a structure in which three layers are laminated one above the other. As shown in the figure, the three weights are provided with a convex portion on the front surface and a concave portion on the back surface, and they are fitted to each other. The second floor stone 205, which is placed on the three laminated weights, also has a concave portion on the back surface and is fitted to the convex portion of the weight 212. As a result, even if an earthquake or the like occurs while the container 206 is lifted, the second floor stone 205 and the weight 212 are prevented from being displaced from each other and the floating container is not out of balance. The second floor stone 205 is made of the same granite as the first floor stone 204. The weight 212 is made of cast iron. The specific densities of granite and cast iron are 2.6 and 7.9, respectively. The floor stone 105 in the first embodiment was entirely granite, but as in the second embodiment, only the function as a decorative stone on the outermost surface is left, and the other parts are replaced with cast iron. Therefore, as compared with the case of the first embodiment, the member that rises integrally with the container can be made heavier. Therefore, the weight of the container 206 can be reduced by that amount to make it easier to take out. When taking out the container 206, following the floor hatch 203, the uppermost layer, the middle layer, and the lowest layer of the weight 212 composed of the second floor stone 205 and the three layers are taken out in order. In this way, the structure arranged on the upper part of the container 206 has one or more integral pieces in a state where they can be separated into two or more pieces or two or more pieces, and each piece is taken out in order. Also has a design intent. When removing the container 206, it is difficult to see how much water has penetrated into the ostomy chamber 209, and therefore it is not known how much buoyancy the container 206 is receiving. If the floor stone 105 as in the first embodiment is removed while receiving a large amount of buoyancy, the container may rise vigorously, resulting in damage to the operator or the internal structure. In particular, immediately after removing the floor stone 105, the container 106 did not rise because it was buried in the mud accumulated over many years between the outer wall of the container and the bone burial chamber 109, and then the container 106 did not rise. It is conceivable that the operator may be injured as a result of the container 106 being released from the mud and rising rapidly when a slight vibration such as touching the container 106 is applied for the work. Therefore, as shown in FIG. 5, the superstructure of the container 206 is divided into several members, and each time the container 206 is taken out, the container 206 is vibrated by hand to suppress the rise even when buoyancy is applied. If it happens, such an accident can be prevented.

FIG. 6 shows a third embodiment of the present invention, and like FIG. 2, is a schematic view showing a cross section taken along the line AA of FIG. 1, showing the structure of the bone burial chamber. However, the shelf 101 shown in FIG. 2 is not drawn. The difference from the embodiment shown in FIG. 2 is that the concrete forming the side surface and the bottom surface of the bone burial chamber 309 is provided with an opening 313 penetrating the surrounding ground 308. The fact that water infiltrates into the bone burial chamber 309 at the same level as the groundwater level in the surrounding ground prevents damage to the foundation structure 307 due to buoyancy and prevents tilting of the tomb as explained in FIG. Desirable from the point of view. When the concrete structure shown in FIG. 2 has insufficient water permeability, an opening 313 can be provided as in the present embodiment to facilitate the ingress of water. Of course, the shape, arrangement, and number of openings are not limited to those shown in FIG. 6, and at least one opening may be formed on the side surface or the bottom surface of the bone burial chamber 309.

FIG. 7 shows a fourth embodiment of the present invention, and like FIG. 6, is a schematic view showing a cross section taken along the line AA of FIG. 1, showing the structure of the bone burial chamber. The first difference from the embodiment shown in FIG. 6 is that a crushed stone layer 414 is provided around the opening 413 provided in the concrete forming the side surface and the bottom surface of the bone burial chamber 409, and crushed stone is provided from the surrounding ground 408. The point is that water is allowed to infiltrate into the bone burial chamber 409 via the layer. The crushed stone layer 414 acts as a filter for removing the earth and sand contained in the groundwater, and functions to suppress the invasion of the earth and sand into the bone burial chamber 409. When earth and sand accumulate in the bone burial chamber 409, as described above, the container 406 is buried in the earth and sand, and when it receives buoyancy, it does not rise as designed, or when the container 406 rises once, it does not rise. When the invaded earth and sand accumulates on the bottom surface of the bone burial chamber 409 and then the water is drained, there is a possibility that the container 406 will not fall completely until it reaches the bottom surface of the bone burial chamber 409 as designed. is there. In addition to providing the crushed stone layer 414, such a function of preventing the intrusion of earth and sand can be realized by using porous concrete or by forming a two-layer structure of a crushed stone layer and a porous concrete layer. Further, since the porous concrete has a shape-retaining property by itself, it is possible to form a part or all of the wall surface of the bone burial chamber 409 with the porous concrete, for example. The second difference from the embodiment shown in FIG. 6 is that a protrusion 418 is provided on the bottom surface of the bone burial chamber 409. By placing the container 406 on the protrusion 418 as shown in the drawing, a gap 415 is created between the bottom surface of the bone burial chamber 409 and the bottom surface of the container 406. Since the void 415 serves as a space for accumulating the invaded earth and sand, the risk of the above-mentioned problems can be further reduced.

FIG. 8 shows a fifth embodiment of the present invention, and like FIG. 2, is a schematic view showing a cross section taken along the line AA of FIG. 1, showing the structure of the bone burial chamber. However, the shelf 101 shown in FIG. 2 is not drawn. The difference from the embodiment shown in FIG. 2 is that the container 506 does not land on the third bottom surface 5073 of the foundation structure 507, which is the bottom of the bone burial chamber 509, and the overhang 510 is the foundation structure. It is placed on the second bottom surface 5072 of the body 507 and holds the container 506. With such a structure, a gap 515 can be provided under the container 506, and as in the fourth embodiment shown in FIG. 7, a space for accumulating invaded earth and sand can be provided.

FIG. 9 shows a sixth embodiment of the present invention, and like FIG. 2, is a schematic view showing a cross section taken along the line AA of FIG. 1, showing the structure of the bone burial chamber. However, the shelf 101 shown in FIG. 2 is not drawn. The difference from the embodiment shown in FIG. 2 is that the bone burial chamber 609 and the container 606 are formed so that the width of the lower portion is smaller than that of the upper portion, and the bottom surface of the bone burial chamber 609 and the bottom surface of the container 606. It is a point that a gap 615 is formed between and. As shown in the figure, the shapes of the bone-feeding chamber 609 and the container 606 are made smaller than the cross-sectional area of the upper part so that the bottom is landed on the inclined surface 616 of the bone-bearing chamber in a state where it is not lifted by buoyancy. Therefore, as shown in the figure, a gap can be provided at the lowermost end of the bone burial chamber. Even with such a structure, it is possible to provide a space for accumulating the invaded earth and sand as in the fourth embodiment shown in FIG.

FIG. 10 shows a seventh embodiment of the present invention, and like FIG. 2, is a schematic view showing a cross section taken along the line AA of FIG. 1, showing the structure of the bone burial chamber. However, the shelf 101 shown in FIG. 2 is not drawn. The difference from the embodiment shown in FIG. 2 is that the O-ring 717 is mounted on the side surface of the container 706 with a recess as shown in the drawing. A metal plate 716 made of stainless steel is fitted in the portion of the wall surface of the bone burial chamber 709 that comes into contact with the O-ring 717, and the O-ring 717 seals between the metal plate 716 and the container 706. When the container 706 is lifted by buoyancy, the O-ring slides on the surface of the metal plate 716 and rises with the container 706. By closing the gap between the container 706 and the bone burial chamber 709 with such a structure, the odor leaked by the water that entered the bone burial chamber, the small animals that entered with the water rise upward, and the vaporized water is on the floor. It is possible to prevent dew condensation on the hatch 703 and dripping on the container 706. Further, even when the container is floating due to the buoyancy, the frictional force of the O-ring suppresses the vibration of the minute container to improve the appearance. Further, it is more preferable that the O-rings 717 are provided at two or two or more locations separated in the vertical direction as shown in the figure. By doing so, the risk of tilting when the container 706 receives buoyancy and rises can be significantly reduced. Needless to say, the installation position of the O-ring 717 does not necessarily have to be as shown in the figure. Further, it is desirable that the shape of the container 706 is not a perfect rectangular parallelepiped but has R at the corner so that the O-ring can be easily installed.

In the first to seventh embodiments of the present invention described above, all the containers are stored in the bone burial chamber, but of course, there may be a plurality of containers.

In the eighth embodiment of the present invention shown in FIG. 11, two containers, a first container 818 and a second container 819, are provided in the bone burial chamber 809. As mentioned above, it may be necessary to remove the installed container from the bone burial chamber for the purpose of repairing the tomb. In this case, if the container is divided into two as shown in FIG. 11, the weight of the container that must be handled at one time is reduced to about half, so that the container can be taken out manually without using a crane or the like. Improves sex. It is also possible to divide the usage for each divided container. For example, a human bone may be stored in the first container, and a pet's ashes may be stored in the second container. When a plurality of containers are housed in the same bone storage chamber as in the present embodiment, it is desirable to connect the containers by easily separable means such as bolts and nuts 812 as shown in the figure. If the containers are not fixed to each other, if the buoyancy received by each container and the total weight of the container and the stored items are different, the amount of rise of each container will be different, and the second floor stone 805 and its upper part will be different. This is because the floor hatch 803 may tilt.

The ninth embodiment of the present invention shown in FIG. 12 shows a case where two containers 818 and 819 are provided in the bone burial chamber 809. Along with the division of the containers, the floor stones and floor hatches placed on the top of each container are also divided. By doing so, even if the buoyancy and weight received for each container change and the ascending / descending behavior differs for each container, the floor stones and floor hatches as described in the eighth embodiment can be formed. There is no need to worry about tilting.

In the tenth embodiment of the present invention shown in FIG. 13, a state in which a container 806 is placed in the bone burial chamber 809 and a plurality of small containers 820 are further housed in the container 806 is shown. Even with such a method, as in the case of the eighth embodiment, advantages such as improvement of workability at the time of taking out and the fact that the use can be divided for each container are maintained.

The present invention has been described above by exemplifying a relatively large-scale tomb found in the permanent memorial tombs shown in FIG. 14 according to the first to tenth embodiments, but the present invention is limited to large-scale tombs. It's not a thing. The relatively small tombs shown in FIG. 20, and other memorial buildings, whether at least part of them are buried underground, have a bone burial chamber. For example, it is a technology that can be used effectively. It goes without saying that the collection is not limited to human bones, but animal bones, grave goods, books, and souvenirs such as lists are also effective.

Although the embodiments and examples of the present invention have been described above, it is planned from the beginning that the configurations of the above-described embodiments and examples are appropriately combined. The embodiments and examples disclosed this time should be considered to be exemplary and not restrictive in all respects. The scope of the present invention is shown by the scope of claims rather than the above description, and it is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

1 Superstructure 2 Floor 3 Flower stand 4 Incense stand 5 Entrance door 7 Foundation structure 11 Shelf 12 Floor 13 Floor hatch 14 Floor stone 18 Ground 19 Bone burial chamber 29 Bone burial chamber 21 Superstructure 39 Opening 41 Shibadai 42 Bone burial chamber 43 Bone tray with ceramic float 44 Ceramic float 45 Wire mesh

101 Shelf 102 Floor 103 Floor Hatch 104 First Floor Stone 105 Second Floor Stone 106 Container 107 Foundation Structure 1071 First Bottom 1072 Second Bottom 1073 Third Bottom 108 Ground 109 Bone Room 110 Overhang 111 Water

203 Floor Hatch 204 First Floor Stone 205 Second Floor Stone 206 Container 207 Foundation Structure 208 Ground 209 Bone Room 212 Weight

303 Floor Hatch 304 First Floor Stone 305 Second Floor Stone 306 Container 307 Foundation Structure 308 Ground 309 Bone Room 313 Opening

403 Floor hatch 404 First floor stone 405 Second floor stone 406 Container 407 Foundation structure 408 Ground 409 Bone chamber 413 Opening 414 Crushed stone layer 415 Void 418 Projection

503 Floor hatch 504 First floor stone 505 Second floor stone 506 Container 507 Foundation structure 508 Ground 509 Bone chamber 510 Overhang 515 Void 5072 Second bottom 5073 Third bottom

603 Floor hatch 604 First floor stone 605 Second floor stone 606 Container 607 Foundation structure 608 Ground 609 Bone chamber 615 Void 616 Inclined surface

703 Floor hatch 704 First floor stone 705 Second floor stone 706 Container 707 Foundation structure 708 Ground 709 Bone chamber 716 Metal plate 717 O-ring

803 Floor Hatch 804 First Floor Stone 805 Second Floor Stone 806 Container 807 Foundation Structure 808 Ground 809 Bone Room 812 Bolts / Nuts 818 First Container 819 Second Container 820 Small Container

8031 Floor hatch 8032 Floor hatch 8051 Second floor stone 8052 Second floor stone

Claims (17)

At least part of it is buried underground, and there is a bone burial chamber where water can enter from the surrounding ground.
It is equipped with a bottomed container placed in the bone-feeding chamber.
The container, when entering the water in the burial chamber, even submerged a part of water, the interior has a structure in which water does not enter immersion, and so that it can be floated and down in the vertical direction , A memorial building characterized by not being fixed to the outside of the container.
The commemorative building according to claim 1, wherein the outer shell of the container, which is exposed to water, is made of stainless steel.
The commemorative construction according to claims 1 and 2, wherein the inner wall of the container is made of a material having corrosion resistance to an acidic solution, particularly an aqueous solution containing at least one of citric acid, glacial acetic acid, and lactic acid. Stuff.
A claim that further includes a structure that is placed or fixed in the container, and that the structure is arranged integrally with the container so that it can rise and fall in the vertical direction. The memorial building according to any one of items 1 to 3.
The memorial structure according to claim 4, wherein when the container and the structure are fixed to each other, they are fixed by a method that can be reversibly separated and combined.
Further comprising a structure which is spaced directly above of the container, and the structure is arranged so that it can be further floating vertically the container becomes the container and integrally at the time of the floating distance between the release The commemorative building according to any one of claims 1 to 4, which is characterized in that it has been constructed.
Any one of claims 4 to 6, wherein each container contains two or more of the above structures, or one or more of the above structures as an integral body in a separable state into two or more pieces. The memorial building described in the section.
The lower end of the placed the container in the burial chamber, if the basement depth exceeds 80cm from the ground surface, weight of the container: the M [kg], from the ground surface of the container The memorial building according to any one of claims 1 to 3 , wherein the volume of a portion of 80 cm or less: V [m ^{3] satisfies the following relationship.}
M ≧ 1.01 × V × 1000
When the lower end of the container on which the structure is placed or fixed is underground at a depth of more than 80 cm from the ground surface, the total weight of the container including the structure : M [kg] and the volume. The memorial structure according to claim 4 or 5 , wherein the volume of a portion 80 cm or less from the ^{ground surface of the container: V [m 3} ] satisfies the following relationship.
M ≧ 1.01 × V × 1000
If the structure is, Ru is arranged so that the container is the container and integrally at the time of the distance g [cm] flying, the total weight of the container containing the structures: and M (kg), the land of the container The memorial structure according to claim 9 , wherein the volume of a portion (80 + g) cm or less from the upper surface: V [m ³ ] satisfies the following relationship.
M ≧ 1.01 × V × 1000
The commemorative building according to any one of claims 1 to 10 , wherein at least one opening is provided on the side surface or the bottom surface of the bone burial chamber.
The memorial structure according to claim 11 , wherein at least one of crushed stone and porous concrete is arranged outside the opening.
In a state where the container has landed on the ground without rising in the bone-feeding chamber, the lower end of the container and the bottom of the bone-feeding chamber are not in close contact with each other, and at least a part thereof is separated to form a gap. The memorial building according to any one of claims 1 to 12, characterized in that.
The commemorative building according to any one of claims 1 to 13 , wherein an O-ring is arranged between the container and the wall surface of the bone burial chamber in which the container is housed.
The commemorative building according to claim 14 , wherein the O-rings are arranged at two or more locations vertically separated from each other.
The memorial building according to any one of claims 1 to 15 , wherein the container is composed of a plurality of parts or a plurality of parts integrated by means that can be separated from each other.
A method of delivering bones, which comprises placing burnt bones in the memorial building according to any one of claims 1 to 16.

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