JP5799475B2 - Domed structure - Google Patents

Description

  The present invention relates to a dome-like structure formed into a dome shape by connecting a plurality of triangular structures having frame members in a three-dimensional manner without gaps.

  Conventionally, as a dome-like structure having a substantially hemispherical appearance, a plurality of triangular structures composed of three frame members are connected in a three-dimensional manner without gaps, thereby forming a substantially hemispherical shape. Things are being used. And the outdoor side surface-like body which covers the outdoor side surface of this triangular structure, and the indoor side surface which covers the indoor side surface of the triangular structure are formed on the inner and outer surfaces of the triangular structure. And a favorable heat insulation performance is acquired by filling the inside of a triangular structure with a heat insulating material. And by forming in this way, even if a frame member is woody, sufficient strength can be exhibited and it can be remarkably lightened. Thereby, the dome-shaped structure can ensure excellent durability that does not easily collapse even in a disaster such as an earthquake or a typhoon.

Conventionally, dome-shaped structures have been used for relatively large buildings for the purpose of use such as exhibition halls, but in recent years, the demand for small general houses with a compact structure has increased (for example, Patent Document 1).
By the way, in the future, with further enhancement of air-conditioning equipment and performance improvement in the future, it is required to have higher heat insulation and higher airtightness than the current situation.

Japanese Patent Laid-Open No. 7-18744

In such a highly enclosed house, there is a small amount of ventilation, moisture tends to be trapped in the room, and there is a risk that the room moisture may enter the wall through a slight gap or the like. When air containing a large amount of water vapor enters and stays in the wall, the durability of the building may be reduced due to internal condensation. Moreover, when moisture is attached to the heat insulating material by condensation using the heat insulating material, the heat insulating property may be remarkably lowered.
In view of the above-mentioned problems, the invention according to claim 1 is a dome-like structure in which the occurrence of condensation in a triangular structure is suppressed , and a plurality of triangular structures having excellent durability and heat insulation are provided continuously. The object is to provide a structure.
In the invention described in claim 2, in addition to the object of the invention described in claim 1 above, in the alternate layer structure, the air in the internal space of the inverted triangular structure is transferred to the internal space of the forward triangular structure in the upper layer. The object is to provide a dome-like structure that moves smoothly and has good ventilation to the upper layer.

In addition to the object of the invention described in claim 1 or claim 2, the invention described in claim 3 enhances the rigidity of the outdoor side surface body and the outdoor side surface body, so that the rigidity of the dome-shaped structure as a whole is increased. An object of the present invention is to provide a dome-like structure that is enhanced and in which a good air flow is formed in the internal space of the triangular structure.
The invention of claim 4, wherein, in addition to the object of the invention according to any one of claims 1 noted above to 3, domed structures working in the field can be a short period of time is extremely simplified can construction The purpose is to provide.

In addition to the object of the invention described in claim 2, the invention described in claim 5 is a dome-like structure in which water vapor that causes condensation is quickly and efficiently discharged to the outside and ventilation in the internal space is promoted. The purpose is to provide.
In addition to the object of the invention described in any one of claims 1 to 5 , the invention described in claim 6 efficiently exhausts humid air in the internal space and insulates the heat insulating material. An object is to provide a dome-like structure whose performance is maintained in a good state.
In addition to the object of the invention described in any one of claims 1 to 6 , the invention described in claim 7 maintains the dry state of the internal space of the triangular structure so that the environment in the internal space is maintained. The object is to provide a dome-like structure that is well maintained and more durable.

(Claim 1)
The invention according to claim 1 is composed of three frame members 50 respectively provided at positions corresponding to the respective sides of the triangle, and fixing means 70 provided at positions corresponding to the respective apexes of the triangle. The dome-like structure 10 formed into a dome shape by connecting a plurality of triangular structures 40 in which the ends of the frame member 50 are connected to each other three-dimensionally without gaps, The triangular structure 40 is formed in a layered structure by stacking a plurality of annularly formed layer structure portions L by connecting the triangular structure 40 without gaps, and the triangular structure 40 is located outside the frame member 50. An outer surface 80 that covers the surface, an edge trunk edge 310 that is fixed as a base material on a surface located outside the outdoor surface 80 along the edge of the triangle, and the edge Fixed to the outside surface of the trunk edge 310 And the outdoor side surface body 90 covering the outdoor side surface body 80 in a state in which the edge body edge 310 is sandwiched between the outdoor side surface body 80 and the edge body edge 310, A communication groove 312 having a concave surface is formed as a communication means 301 that communicates from the internal space 100 between the outdoor side surface 80 and the outdoor side surface 90 toward the adjacent triangular structure 40. In the hierarchical structure, as the layer structure portion L, the triangle structure 40 (hereinafter, referred to as “forward triangle structure 42”) in contact with the upper layer only at the apex of the triangle and the upper layer with the sides of the triangle. The triangular structure 40 (hereinafter referred to as “inverted triangular structure 41”) in contact with each other has an alternating layer structure portion 20 alternately arranged on the circumference, and the alternating layer structure portion 20 is adjacent to each other. Each of the above-mentioned triangles located at the boundary between the forward triangular structure 42 and the inverted triangular structure 41 An adjacent communication portion 360 that communicates from the internal space 100 of the forward triangular structure 42 to the internal space 100 of the inverted triangular structure 41 that is adjacent in the same hierarchy via the communication means 301 of the edge trunk edge 310. It is formed.

Here, the “dome-shaped structure 10 formed in a dome shape by connecting a plurality of triangular structures 40 three-dimensionally without gaps” is a so-called geodesic dome or a fuller dome or the like. It means the structure of the shape.
Further, the “frame member 50” is a skeleton of the dome-shaped structure 10 and is provided at a position corresponding to each side of each triangular structure 40 constituting the dome-shaped structure 10. It is.
Here, a connector 71 that connects the ends of the frame member 50 to each other can be used as the “fixing means 70”.
In the fixing means 70, the triangular members of the triangular structure 40 are formed by connecting the frame members 50 corresponding to the respective sides of the triangle of the triangular structure 40 with the fixing means 70 at the positions of the apexes of the triangles. At the same time, the ends of the frame members 50 of other adjacent triangular structures 40 are also connected by the fixing means 70. Thereby, a plurality of triangular structures 40 are continuously provided.
Then, a dome is formed from a frame member 50 provided at a position corresponding to each side of the triangle of each triangular structure 40 and a fixing means 70 provided at a position corresponding to each vertex of the triangle of each triangular structure 40. The dome-shaped truss skeleton serves as the structural frame of the dome-shaped structure 10.
The “forward triangle structure 42” is a triangular structure 40 that is in contact with the upper layer only at the apex of the triangle in the alternating layer structure unit 20, and is an upward triangle having the apex at the top and the bottom at the bottom.

In addition, the “inverted triangular structure 41” is an inverted triangular triangular structure 40 that touches the upper layer with a triangular side in the alternate layer structure unit 20, and has a downward triangle having a vertex at the bottom and a base at the top. means.
Further, the “communication means 301” is a triangular structure which is a space such as a hole or a groove provided in the edge trunk edge 310 and is adjacent to the internal space 100 between the outdoor side surface 80 and the outdoor side surface 90. It communicates with the edge trunk edge 310 toward the body 40 side. Specifically, as the “communication means 301”, for example, a communication hole penetrating in the width direction of the edge trunk edge 310 from the inner space 100 side of the edge trunk edge 310 toward the adjacent triangular structure 40 side, A communication groove that communicates from the inner space 100 side of the rim trunk edge 310 toward the adjacent triangular structure 40 side and that is recessed in a cross-sectional concave shape on the surface of the outdoor side body 80 side or the outdoor side body 90 side (specifically, For example, an edge trunk edge communication groove 312) is formed.

In addition, here, “through the communication means 301 of each edge trunk edge 310 located at the boundary between the adjacent forward triangular structure 42 and the inverted triangular structure 41” means an alternating layer structure portion. The communication means 301 (specifically, the edge trunk edge 310 of both the forward triangle structure 42 and the inverted triangle structure 41 located at the boundary between the forward triangle structure 42 and the inverted triangle structure 41 that are adjacent to the same 20 layers in the same hierarchy. Means that it is via the marginal trunk edge communication means 311).
Communication means 301 (specifically, the peripheral trunk edge communication means 311) of the peripheral trunk edge 310 of the forward triangular structure 42 and communication means 301 (specifically, the peripheral trunk edge 310 of the adjacent inverted triangular structure 41) Specifically, the adjacent communication portion 360 that communicates from the inner space 100 of the forward triangular structure 42 to the inner space 100 of the adjacent inverted triangular structure 41 is formed via the edge trunk connecting means 311). . Ventilation from the internal space 100 of the forward triangular structure 42 to the internal space 100 of the inverted triangular structure 41 is performed through the adjacent communication part 360 in the alternate layer structure 20 of the same hierarchy.

In the present invention, the edge trunk edge 310 as a base material is fixed between the edges of the outdoor side face 80 and the outdoor side face 90 in a state of being sandwiched. For this reason, the edge of the outdoor side surface 90 is prevented from being deformed or damaged by an external force, and the rigidity of the triangular structure is increased. As a result, the rigidity of the dome-shaped structure 10 as a whole is also increased.
In the present invention, even if air containing a large amount of water vapor enters the internal space 100 between the outdoor side surface 80 and the outdoor side surface 90 of the forward triangular structure 42 of the alternating layer structure 20, the adjacent communication The air containing moisture diffuses and moves to the internal space 100 of the inverted triangular structure 41 adjacent to the left and right of the forward triangular structure 42 via the part 360. Specifically, each of the edge trunks located at the boundary between the forward triangle structure 42 and the inverted triangle structure 41 adjacent to each other in the same hierarchy is the air containing moisture in the internal space 100 of the forward triangle structure 42 It moves to the inner space 100 of the left and right inverted triangular structures 41 via the communication means 301 of 310. Thereby, moisture containing moisture is prevented from staying in the internal space 100 of the specific triangular structure 40 in the dome-shaped structure 10. Therefore, the occurrence of condensation in the internal space 100 of the triangular structure 40 of the dome-shaped structure 10 is suppressed. As a result, the internal space 100 of the triangular structure 40 is kept dry, and the environment of the internal space 100 of the triangular structure 40 is well maintained. Further, even if air containing moisture is present inside the triangular structure 40 and on the indoor side of the outdoor side surface 80, the air is diffused and moved through the internal space 100 of the triangular structure 40. Is possible. This makes it possible to provide a durable dome-like structure 10. Even when a heat insulating material is used in the triangular structure 40, the inside of the triangular structure 40 is in a dry state, so that the occurrence of condensation is suppressed, thereby preventing moisture from adhering to the heat insulating material. And the deterioration of the heat insulation performance is suppressed.

(Claim 2)
The invention according to claim 2 is characterized in that, in addition to the features of the invention according to claim 1, the alternating layer structure unit 20 includes the inverted triangular structure 41 and the forward triangular structure 42 on the upper layer in contact with the inverted triangular structure 41. Communicating from the internal space 100 of the inverted triangular structure 41 to the internal space 100 of the forward triangular structure 42 located in the upper layer thereof via the communication means 301 of each of the marginal body edges 310 positioned at the boundary The upper layer communication portion 370 is formed.
Here, "through the communication means 301 of each edge trunk 310 located at the boundary between the inverted triangular structure 41 and the upper forward triangular structure 42 in contact with the inverted triangular structure 41" means that the inverted triangular structure 41 and this The upper forward triangular structure 42 in contact with each other, the communication means 301 (specifically, the peripheral trunk edge communication means 311) of the edge trunk edge 310 of the inverted triangular structure 41 located at the boundary between them, This means that both the communicating means 301 (specifically, the edge trunk edge communicating means 311) of the edge trunk edge 310 of the forward triangular structure 42 located at the boundary of the forward triangle structure 42 are interposed.

The communication means 301 (specifically, the edge trunk edge communication means 311) of the edge trunk edge 310 located at the boundary of the inverted triangular structure 41 and the boundary of the forward triangle structure 42 of the upper layer in contact therewith The forward triangular structure 42 located in the upper layer from the internal space 100 of the inverted triangular structure 41 via the communication means 301 (specifically, the peripheral edge trunk communication means 311) of the positioned edge trunk edge 310. An upper layer communication portion 370 communicating with the inner space 100 is formed. Ventilation to the upper layer is performed in the alternate layer structure unit 20 through the upper layer communication unit 370.
The moisture-containing air in the internal space 100 of the triangular structure 40 expands due to heat from the outside or the indoor side, increases in volume, and moves upward. In the inverted triangular structure 41, the cross-sectional area increases as the horizontal cross section becomes higher. As a result, the air that is going to rise while increasing the volume moves smoothly upward in the internal space 100 of the inverted triangular structure 41 and is also diffused as it moves upward. The air finally reaches the edge trunk edge 310 located on the side where the horizontal cross-sectional area of the inverted triangular structure 41 is the largest (so-called bottom side) and located on the boundary in contact with the upper layer. Reached air passes through the communication means 301 of the edge trunk edge 310 and the communication means 301 of the edge trunk edge 310 located at the boundary of the upper-order forward triangle structure 42 to the inside of the forward triangle structure 42. Move into space 100. As a result, the air in the internal space 100 of the inverted triangular structure 41 moves smoothly to the internal space 100 of the upper forward triangular structure 42. As a result, the air movement to the upper layer is favorably performed in the alternate layer structure portion 20.

(Claim 3)
The invention described in claim 3 is characterized in that, in addition to the features of the invention described in claim 1 or 2, the surface located outside the outdoor surface-like body 80 has a longitudinal direction inside the triangle. A vertical trunk rim 320 is formed, and a plurality of small spaces 143 partitioned by the vertical trunk rim 320 are formed in the internal space 100 of the triangular structure 40. A communication means 301 (specifically, a vertical trunk edge communication means 321) that communicates from one small space 143 partitioned by a vertical trunk edge 320 to the other small space 143 is formed.
A vertical trunk edge 320 along the vertical direction is formed between the outdoor side surface 80 and the outdoor side surface 90 inside the triangle of the triangular structure 40. As a result, the deformation of the outdoor side surface 90 inside the triangle of the triangular structure 40 is suppressed, and the rigidity of the outdoor side surface 90 and the outdoor side surface 80 is increased. As a result, the rigidity of the dome-shaped structure 10 as a whole can be increased.

In the internal space 100 of the triangular structure 40, a small space 143 partitioned by the vertical trunk edge 320 is formed, and from the small space 143 partitioned by the vertical trunk edge 320 to the other small space 143, the vertical trunk edge 320 is formed. A communication means 301 (specifically, a vertical body edge communication means 321) is formed. For this reason, the movement of the air between the small spaces 143 partitioned by the vertical trunk edge 320 is not hindered, and the air in the internal space 100 can move freely. Accordingly, good air flow in the internal space 100 of the triangular structure 40 is Ru is maintained.

(Claim 4 )
The invention according to claim 4 is characterized in that, in addition to the features of the invention according to any one of claims 1 to 3 , the triangular structure 40, the outdoor side surface 80, and the outdoor side surface 90. A triangular structure panel 160 having a triangular shape in plan view having at least the edge trunk edge 310 is formed, and a plurality of the triangular structure panels 160 are three-dimensionally connected without a gap to be formed in a dome shape. It is characterized by being.
Here, the triangular structure panel 160 has a triangular shape in plan view including at least the outdoor side surface 80, the outdoor side surface 90, and the edge trunk edge 310.

Such a triangular structure panel 160 can be worked in the field in an integrated state in advance, so that the work at the work site can be extremely simplified and the construction can be performed in a short time.
(Claim 5 )
The invention according to claim 5 is characterized in that, in addition to the features of the invention according to claim 2, the outdoor side surface 90 of the triangular structure 40 located in the layer structure portion L of the upper layer includes the internal An exhaust hole 110 that is open to the outdoors from the space 100 is provided, and an intake hole 120 that is open to the outdoors from the internal space 100 is provided at the lower end of the triangular structure 40 located in the lowermost layer structure portion L. The triangular structure 40 is provided with a ventilation layer 350 communicating from the intake hole 120 to the exhaust hole 110 through the adjacent communication part 360 and the upper layer communication part 370.

Here, the “vent layer 350” is a space that communicates from the intake hole 120 to the exhaust hole 110, and generates a natural air flow in the internal space 100 around the triangular structure 40 of the dome-shaped structure 10. It is something to be made.
In the present invention, outdoor air enters through the intake holes 120 at the lower end of the triangular structure 40 located in the lowermost layer structure portion L of the hierarchical structure. The air that has entered through the intake hole 120 expands due to a rise in temperature caused by sunlight irradiation on the outdoor side, a rise in temperature caused by heat of indoor heating, etc., and the internal space as the ventilation layer 350 Ascend within 100. The ascending air moves from the internal space 100 of the forward triangular structure 42 of the alternating layer structure unit 20 to the internal space 100 of the inverted triangular structure 41 adjacent in the same level via the adjacent communication unit 360. The moved air moves from the internal space 100 of the inverted triangular structure 41 to the internal space 100 of the forward triangular structure 42 adjacent to the upper layer via the upper layer communication portion 370. Eventually, the moved air moves to the internal space 100 of the triangular structure 40 of the upper layer structure portion L of the hierarchical structure. The moved air is exhausted from the internal space 100 as the ventilation layer 350 of the upper triangular structure 40 through the exhaust hole 110 of the outdoor side surface 90 to the outside. That is, the air that has entered the internal space 100 of the triangular structure 40 from the intake hole 120 located in the lowest layer of the hierarchical structure passes through the internal space 100 to the exhaust hole 110 located in the upper layer, and the triangle of the dome-shaped structure 10 The inside of the internal space 100 of the structure 40 rises. In this way, an air flow that naturally rises from the intake hole 120 toward the exhaust hole 110 is formed in the internal space 100 as the ventilation layer 350 of the triangular structure 40. Thus, even when humid air enters from the indoor side into the internal space 100 surrounded by the outdoor side surface 80 and the outdoor side surface 90, the air flows efficiently in the ventilation layer 350. It is discharged outside through the exhaust hole 110. Therefore, water vapor that causes condensation is quickly discharged to the outdoors. As described above, the ventilation layer 350 that generates a natural air flow is formed on the entire surface of the dome-shaped structure 10 in the triangular structure 40, whereby ventilation in the internal space 100 of the triangular structure 40 is promoted. The

(Claim 6 )
The invention described in claim 6 is characterized in that, in addition to the feature of the invention described in any one of claims 1 to 5 , a heat insulating layer 130 made of a heat insulating material is provided on the indoor side of the outdoor sheet 80. It is formed.
Here, "heat insulation" is a material for suppressing heat conduction. For example, fiber insulation such as glass wool, rock wool or cork, and foam insulation such as urethane foam or phenol foam are used as the material. In addition, as the shape, a board shape, a felt shape, a rose shape, an in-situ foaming, or the like can be used.

A heat insulating layer 130 is formed on the indoor side of the outdoor sheet 80. Thus, the ventilation layer 350 is not filled with a heat insulating material, and the entire space in the ventilation layer 350 is used as a space for moving the rising air.
In general, when the heat insulating layer 130 is provided in a part of the air-permeable layer 350, the air-permeable layer 350 can be used for ventilation only in a part of the space where the heat-insulating layer 130 is not provided. Compared to a case where a space for ventilation is provided only in a part of the ventilation layer 350, the present invention can generate a large amount of air flow in the ventilation layer 350. Thereby, the humid air in the ventilation layer 350 can be efficiently discharged, and the environment inside the triangular structure 40 is further improved.

Further, the heat insulating layer 130 is formed on the indoor side of the outdoor planar body 80. For this reason, in the winter season when the outdoor temperature is low, the heat insulating layer 130 is strongly influenced by the air in the indoor side where the temperature is higher than in the interior space 100 close to the outdoors or outdoors. As a result, the heat insulating layer 130 is formed in air having a relatively high temperature and a high saturated water vapor amount as compared with the case where the heat insulating layer 130 is formed in the ventilation layer 350 or the outdoor side of the outdoor side surface 90. As a result, the possibility of dew condensation occurring in the heat insulating layer 130 itself can be reduced. Thereby, the heat insulation performance of the heat insulation layer 130 is maintained in a good state.
(Claim 7 )
The invention according to claim 7 is characterized in that, in addition to the feature of the invention according to any one of claims 1 to 6 , the moisture-proof layer 380 made of the moisture-proof sheet 381 is provided on the indoor side of the outdoor-side sheet 80. Is formed.

Here, the “moisture-proof sheet” is a sheet used to prevent moisture and water vapor from permeating, and a moisture-proof polyethylene sheet, asphalt roofing, a plastic film, or the like can be used.
By providing the moisture-proof layer 380 with the moisture-proof sheet 381 on the indoor side of the outdoor sheet 80, moisture from the indoor side can be prevented from entering the triangular structure 40. As a result, the internal space 100 of the triangular structure 40 is further maintained in a dry state, and the environment of the internal space 100 of the triangular structure 40 is maintained well, and a more durable dome-shaped structure 10 can be provided. Become.
In addition, by providing the moisture-proof layer 380 on the indoor side of the heat-insulating layer 130, it is possible to suppress moisture on the indoor side from reaching the heat-insulating layer 130, and as a result, a decrease in heat-insulating performance is suppressed and good heat-insulating performance is achieved. Can be maintained.

Since this invention is comprised as mentioned above, there exists an effect as described below.
According to the first aspect of the present invention, there is provided a dome-like structure in which the occurrence of dew condensation in a triangular structure is suppressed , and a plurality of triangular structures are continuously provided, which are excellent in durability and heat insulation. be able to.
According to the invention described in claim 2, in addition to the effect of the invention described in claim 1 above, in the alternating layer structure, the air in the internal space of the inverted triangular structure is the internal space of the forward triangular structure in the upper layer. It is possible to provide a dome-like structure that moves smoothly and smoothly vents to the upper layer.
According to the invention described in claim 3, in addition to the effects of the invention described in claim 1 or 2, the rigidity of the outdoor side surface body and the outdoor side surface body is increased, so that the dome-like structure as a whole is also rigid. And a dome-like structure in which a good air flow is formed in the internal space of the triangular structure can be provided.

According to the fourth aspect of the invention, in addition to the effect of the invention according to any one of claims 1 described above to 3, domed capable in a short time also the construction can extremely simplify working with onsite A structure can be provided.
According to the invention described in claim 5 , in addition to the effect of the invention described in claim 2, the dome-like structure in which water vapor that causes condensation is quickly and efficiently discharged to the outside and ventilation in the internal space is promoted. Things can be provided.

According to the invention described in claim 6 , in addition to the effect of the invention described in any one of claims 1 to 5 , the humid air in the internal space is efficiently discharged and the heat insulating material It is possible to provide a dome-like structure that maintains a good thermal insulation performance.
According to the invention of claim 7, wherein, in addition to the effect of the invention according to any one of claims 1 to 6, drying of the interior space of the triangular structure is to maintain the environment in the internal space Can be maintained well, and a more durable dome-like structure can be provided.

It is a 1st embodiment of the present invention, and is an appearance perspective view showing a triangular structure of a dome-like structure. BRIEF DESCRIPTION OF THE DRAWINGS It is a 1st Embodiment of this invention, Comprising: It is an external appearance front view which shows the frame member and connector of a triangular structure. It is a 1st embodiment of the present invention, and is the appearance front view showing the outdoor side planar object of a triangular structure, and the trunk edge fixed to the outdoor side of this outdoor side planar object. BRIEF DESCRIPTION OF THE DRAWINGS It is the 1st Embodiment of this invention, Comprising: It is an external appearance perspective view which shows the edge trunk edge and the edge trunk edge communication groove provided in it. FIG. 1 is a cross-sectional view showing a triangular structure according to a first embodiment of the present invention. FIG. FIG. 2 is a longitudinal sectional view showing the vicinity of an exhaust hole in the first embodiment of the present invention. FIG. 2 is a longitudinal sectional view showing the vicinity of an intake hole according to the first embodiment of the present invention. It is the 2nd Embodiment of this invention, Comprising: It is an external appearance front view which shows a triangular structure panel.

(First embodiment)
As shown in FIG. 1, the dome-like structure 10 according to the first embodiment includes a plurality of triangular structures 40 each including three frame members 50 provided at positions corresponding to the respective sides of the triangle. It is formed in a dome shape by being arranged three-dimensionally without any gaps.
The dome-like structure 10 is formed by a hierarchical structure in which five layers of the layer structure portion L formed in an annular shape by connecting the triangular structures 40 without gaps are stacked.
The layer structure portion L has a first structure portion 11 which is a topmost structure portion and has a shape in which five triangular structures 40 inscribed in the same sphere are combined in a pentagonal shape without gaps. Yes. The layer structure portion L is connected to the first structure portion 11 below the first structure portion 11 without a gap, and the 15 triangular structures 40 inscribed in the same sphere are formed without a gap. It has the 2nd structure part 12 of the shape combined circularly. The layer structure portion L is connected to the second structure portion 12 below the second structure portion 12 without gaps, and the 25 triangular structures 40 inscribed in the same sphere are formed without gaps. It has the 3rd structure part 13 of the shape combined cyclically | annularly. The layer structure portion L is connected to the lower side of the third structure portion 13 without any gap with the third structure portion 13, and 30 triangular structures 40 inscribed in the same sphere are annularly formed with no gap. The fourth structure portion 14 is combined with the fourth structure portion 14. The layer structure portion L is connected to the fourth structure portion 14 below the fourth structure portion 14 without gaps, and has a shape in which 30 triangular structures 40 are annularly combined without gaps. It has a fifth structure part 15. The fifth structural portion 15 is fixed on a foundation 30 made of concrete.

  In the present embodiment, in the second structure portion 12 to the fifth structure portion 15, the triangular structure 40 in the same hierarchy has a forward triangle structure in which two vertices are arranged on the lower side and one vertex is arranged on the upper side. There are two types of triangular structures 40: a body 42 and an inverted triangular structure 41 having one vertex on the lower side and two vertices on the upper side. The forward triangular structure 42 is in contact with the upper layer only at the apex of the triangle, and the inverted triangular structure 41 is in contact with the upper layer with the sides of the triangle. That is, the inverted triangular structure 41 is a so-called “inverted triangle”. And as the layer structure part L of the same hierarchy from the 2nd structure part 12 to the 5th structure part 15, the alternating layer structure part by which the forward triangle structure 42 and the inverted triangle structure 41 were alternately arrange | positioned on the circumference 20 is formed. In the first structure portion 11, only the forward triangular structure 42 is formed.

In the present embodiment, the first structure portion 11 to the fourth structure portion 14 are composed of a large number of triangular structures 40 that are inscribed in the same sphere having the radius R, and the fifth structure portion 15 has the same radius R. It is composed of a large number of triangular structures 40 inscribed in the cylinder.
The dome-like structure 10 includes connectors 71 as fixing means 70 that connect the ends of the frame member 50 and are provided at positions corresponding to the apexes of the triangles of the triangular structure 40, respectively.
Then, from the frame member 50 provided at a position corresponding to each side of each triangular structure 40 and the connector 71 as a fixing means 70 provided at a position corresponding to each vertex of each triangular structure 40, FIG. The dome-shaped truss skeleton shown in Fig. 1 is constructed. The dome-shaped truss skeleton serves as a structural housing of the dome-shaped structure 10.

The connector 71 is made of metal, and the frame member 50 is made of wood. Of course, the material is not limited to this, and the material of the frame member 50 may be a metal.
A connector 71 provided at the lower end of the fifth structure portion 15 is a base connector 72. The base connector 72 is for connecting the end portions of the frame member 50 gathering at the apex of the lower end of the fifth structure portion 15. Further, the base connector 72 functions as a member for connecting the ends of the four frame members 50 and also functions as a member for joining the truss skeleton to the foundation.
A connector 71 provided on the boundary line between the fourth structure portion 14 and the fifth structure portion 15 is referred to as a beam connector 73. The beam connector 73 is for connecting the end portions of the six frame members 50 gathering at the apex on the boundary line between the fourth structure portion 14 and the fifth structure portion 15.

A connector 71 other than the base connector 72 and the beam connector 73, and five arms of the connector 71 provided at a position where the ends of the five frame members 50 gather (position where the vertices of the five triangular structures 40 gather) Connector 74 is assumed. The 5-arm connector 74 is for connecting the ends of the five frame members 50 gathered at that position.
6 connectors 71 other than the base connector 72 and the beam connector 73, each of which is provided at a position where the ends of the six frame members 50 are gathered (position where the apexes of the six triangular structures 40 are gathered). The connector 75 is used. The 6-arm connector 75 is for connecting the ends of the six frame members 50 gathered at that position.

As shown in FIG. 2, in one triangular structure 40, frame members 50 are arranged at positions corresponding to the respective sides of the triangle. The ends of the frame member 50 are fixed with a connector 71. A triangular structure 40 shown in FIG. 2 represents one of the triangular structures 40 of the third structure portion 13, and the connector 71 arranged at the position corresponding to the apex of the triangle has 6 An arm connector 75 is formed.
The 6-arm connector 75 is used to join a frame member 50 to a cylindrical hub 76, a flat plate-like reinforcing plate portion 78 provided so as to close one opening of the hub 76, and the frame member 50. And six flat plate-like arms 77 projecting outward from the outer peripheral surface of 76.

The number of the arms 77 is the same as the number of frame members 50 that gather at the apex of the triangle where the 6-arm connector 75 is disposed. Six frame members 50 gather at the apex of the triangle where the 6-arm connector 75 is disposed. For this reason, six arms 77 are provided. Each arm 77 corresponds to each frame member 50 on a one-to-one basis. That is, one frame member 50 is joined to one arm 77.
Each arm 77 has an end joined to both the outer peripheral surface of the hub 76 and the reinforcing flat plate portion 78. Thereby, the strength sufficient to support one frame member 50 by one arm 77 is exhibited.

The frame member 50 is disposed at a position corresponding to each side of the triangular structure 40. The frame member 50 is formed from a wood having a rectangular parallelepiped shape as a whole. The end of the frame member 50 is fixed to the arm 77 of the connector 71 with bolts and nuts (not shown). The three frame members 50 provided at positions corresponding to the sides of the triangle are connected by the connector 71, whereby the triangular structure 40 serving as a triangular truss skeleton is formed.
Each triangular structure 40 is formed with an outer planar body 80 that covers a triangular surface located on the outdoor side of one triangular structure 40 (see FIG. 5). Further, each triangular structure 40 is formed with a trunk edge 300 made of wood that is fixed as a base material on a surface located outside the outdoor planar body 80 (see FIG. 5). Furthermore, each triangular structure 40 is fixed to a surface of the trunk rim 300 positioned on the outdoor side, and covers the outdoor side planar body 80 with the trunk rim 300 sandwiched between the outer circumferential plane 80 and each triangular structure 40. An outdoor side surface 90 is formed (see FIG. 5). The outdoor side surface 90 and the outdoor side surface 80 are triangular flat plates made of wood. In the triangular structure 40, an internal space 100 is formed between the outdoor side surface 90 and the outdoor side surface 80 with the trunk edge 300 interposed therebetween (see FIG. 5). Furthermore, each triangular structure 40 is formed with an indoor side surface body 225 that covers a triangular surface located on the indoor side of one triangular structure 40 (see FIG. 5). The indoor side surface body 225 is an interior finishing material 220 facing the indoor side. Inside the triangular structure 40, an indoor space 226 is formed between the outdoor side surface 80 and the indoor side surface 225 (see FIG. 5).

In the indoor space 226 of the triangular structure 40, the reinforcing member 140 is passed between the outdoor sheet 80 and the indoor side panel 225, and supports the outdoor sheet 80 and the indoor side panel 225. Is formed.
Specifically, the reinforcing member 140 includes three vertical reinforcing members 141 arranged in the vertical direction and one horizontal reinforcing member 142 arranged in the horizontal direction. By the vertical reinforcing member 141 and the horizontal reinforcing member 142, the indoor space 226 of the triangular structure 40 is divided into five spaces.
As shown in FIG. 3, the trunk edge 300 includes a marginal trunk edge 310 along a triangular edge of the triangular structure 40, a vertical trunk edge 320 along the longitudinal direction inside the triangle of the triangular structure 40, and a triangle And a short top trunk edge 330 disposed in the vicinity of the apex of the triangle of the structure 40.

A total of three edge trunk edges 310 are formed in one triangular structure 40 along the three edges of the triangle. A total of four vertical body edges 320 are formed in the vertical direction at positions such that the bottom sides of the triangular structure body 40 are equally divided into approximately five equal intervals. A total of six top trunk edges 330 are formed in one triangular structure 40 by arranging two short ones at three apexes of the triangle.
Each trunk edge 300 is formed with communication means 301 that communicates at right angles to the longitudinal direction of the trunk edge 300 when the trunk edge 300 is viewed from the outdoor side. Specifically, the edge trunk edge 310 communicates from the inner space 100 between the outdoor side body 80 and the outdoor side body 90 toward the adjacent triangular structure 40 side. Means 311 are formed. The edge trunk edge communication means 311 is formed of a peripheral edge trunk edge communication groove 312 having a concave cross-sectional shape along the longitudinal direction of the trunk edge 300 (see FIG. 5). In the internal space 100 of the triangular structure 40, a plurality of small spaces 143 partitioned by the vertical trunk edge 320 and the top trunk edge 330 are formed. The vertical trunk edge 320 is formed with a vertical trunk edge communication means 321 that communicates from one small space 143 partitioned by the vertical trunk edge 320 to the other small space 143. The vertical trunk edge communication means 321 is formed of a vertical trunk edge communication groove 322 having a concave cross-sectional shape along the longitudinal direction of the trunk edge 300. The top trunk edge 330 is formed with a top trunk edge communication means 331 that communicates from one small space 143 partitioned by the top trunk edge 330 to the other small space 143. The top trunk edge communication means 331 is formed from a top trunk edge communication groove 332 having a concave cross-sectional shape along the longitudinal direction of the trunk edge 300.

  In the alternate layer structure 20, the communication means 301 (specifically, the edge trunk edge) of each edge trunk edge 310 located at the boundary between the forward triangle structure 42 and the inverted triangle structure 41 adjacent in the same layer. An adjacent communication portion 360 that communicates from the internal space 100 of the forward triangular structure 42 to the internal space 100 of the inverted triangular structure 41 that is adjacent in the same hierarchy is formed via the communication means 311). That is, the adjacent communication portion 360 is the edge trunk edge of the edge trunk edge 310 of the inverted triangular structure 41 adjacent to the edge trunk edge communication means 311 of the edge trunk edge 310 of the forward triangle structure 42 in the same layer. It communicates from the internal space 100 of the forward triangular structure 42 to the internal space 100 of the adjacent inverted triangular structure 41 via the communication means 311. Through the adjacent communication portion 360, ventilation is performed from the internal space 100 of the forward triangular structure 42 to the internal space 100 of the inverted triangular structure 41 adjacent in the same layer in the alternate layer structure 20 of the same level.

  In the alternating layer structure 20, the communication means 301 (specifically, the edge trunk edge) of each edge trunk edge 310 located at the boundary between the inverted triangular structure 41 and the upper forward triangle structure 42 in contact with the inverted triangle structure 41. An upper layer communicating portion 370 is formed through the communicating means 311) to communicate from the inner space 100 of the inverted triangular structure 41 to the inner space 100 of the forward triangular structure 42 located in the upper layer. That is, the upper layer communication portion 370 is positioned at the boundary between the edge trunk edge communication means 311 of the edge trunk edge 310 located at the boundary of the inverted triangular structure 41 and the upper layer forward triangle structure 42 in contact therewith. It communicates from the internal space 100 of the inverted triangular structure 41 to the internal space 100 of the forward triangular structure 42 located in the upper layer thereof via the peripheral body edge communication means 311 of the peripheral body edge 310. Ventilation to the upper layer is performed in the alternate layer structure unit 20 through the upper layer communication unit 370.

  As shown in FIG. 4, the edge trunk edge 310 is formed with an edge trunk edge communication groove 312 as the edge trunk edge communication means 311 communicating at right angles to the longitudinal direction. The marginal trunk edge communication groove 312 has a semi-elliptical cross-sectional shape along the longitudinal direction of the trunk edge 300. Of course, the groove shape of the edge trunk edge communication groove 312 is not limited to this, and the sectional shape along the longitudinal direction of the trunk edge 300 may be other shapes such as a semicircular shape, a quadrangular shape, a triangular shape, and the like. . Further, the edge trunk edge communication means 311 may not be a groove shape like the edge trunk edge communication groove 312 but may be a hole penetrating at right angles to the longitudinal direction of the trunk edge 300. In addition, the cross-sectional shape along the longitudinal direction of the body edge 300 of the hole can be selected from various shapes such as an elliptical shape, a circular shape, a rectangular shape, and a triangular shape.

In the present embodiment, the marginal trunk edge 310 is fixed by a nail or the like to the outdoor side of the outdoor-side planar body 80 with the surface on which the peripheral trunk-rim communication groove 312 is formed facing the indoor side. The direction in which the edge trunk edge 310 is attached is not limited to this, and the outdoor outer surface-shaped body 80 is formed such that the surface of the edge trunk edge 310 on which the edge trunk edge communication groove 312 is formed faces the outdoor side. It can also be fixed to.
The shape and mounting direction of the edge trunk edge communication groove 312 described above are not limited to the edge trunk edge communication groove 312 of the edge trunk edge 310, but the vertical trunk edge of the vertical trunk edge 320. The same applies to the communication groove 322 and the top trunk edge communication groove 332 of the top trunk edge 330.
As shown in FIG. 5, a single frame member 50 is formed between two adjacent triangular structures 40. The edge trunk edge 310 is fixed to the edge of the triangle of the triangular structure 40 in a state of being sandwiched between the outdoor side surface 90 and the outdoor side surface 80. The edge trunk edge 310 is formed with an edge trunk edge communication groove 312 that communicates from the internal space 100 between the outdoor side body 80 and the outdoor side body 90 toward the adjacent triangular structure 40 side. Yes. By forming the marginal trunk edge communication groove 312, it functions as a ventilation layer 350 that allows the adjacent internal spaces 100 to communicate with each other. The frame member 50 shown in FIG. 5 is disposed between adjacent triangular structures 40 in the same level. In FIG. 5, the right triangle structure 40 in the figure is formed by a forward triangle structure 42, and the left triangle structure 40 in the figure is formed by an inverted triangle structure 41. In this case, the air in the internal space 100 of the forward triangle structure 42 expands due to a temperature rise, and the peripheral trunk edges 310 of the forward triangle structure 42 and the inverted triangle structure 41 extend from the internal space 100 of the forward triangle structure 42. It moves to the internal space 100 of the inverted triangular structure 41 through the peripheral edge trunk edge communication groove 312.

A waterproof sheet 180 is attached to the outdoor side of the outdoor sheet 80 of each triangular structure 40 to prevent outside moisture from entering the indoor side. Specifically, asphalt hoofing is used for this waterproof sheet 180. An outer surface material 190 for protecting the dome-like structure 10 from wind and rain is formed on the outdoor side of the waterproof sheet 180. The outer surface material 190 functions as a roof material in the upper layer and functions as a wall material in the lower layer. A ceramic material is used as the material of the outer surface material 190.
The outdoor side surface 80, the side edge body 310, and the outdoor side surface 90 of the triangular structure 40 are fixed to the frame member 50 by fasteners 230 made of nails.

A heat insulating layer 130 made of a heat insulating material for suppressing heat conduction is formed on the indoor side of the outdoor side planar body 80 of the triangular structure 40. As the heat insulating layer 130, a board-like material in which a fiber heat insulating material containing rock wool or the like is pressed is used. Although not shown in particular, a gap generated between two adjacent heat insulating layers 130 is filled with urethane foam, which is a foam heat insulating material.
A moisture-proof sheet 381 is formed on the indoor side of the heat insulating layer 130. An interior finishing material 220 as an indoor side surface body 225 is formed on the indoor side of the moisture-proof sheet 381. A moisture-proof sheet 381 is attached to the outdoor side of the interior finishing material 220. A corner finishing material 221 that covers the corner from the indoor side is formed at the corner of the interior finishing material 220 on the indoor side.

  As shown in FIG. 6, one triangular structure 40 out of the five triangular structures 40 of the first structure portion 11 is formed with an exhaust hole 110 for discharging the air in the internal space 100 to the outdoors. Has been. The exhaust hole 110 is formed with a hood member 111 that covers the upper portion of the exhaust hole 110 and prevents entry of wind and rain from the outside. The hood member 111 includes a fixed piece 117 fixed to the adjacent outdoor sheet 80, a bent piece 118 that is bent from the upper end of the fixed piece 117 and covers the upper portion of the exhaust hole 110, and a middle portion of the bent piece 118. One end is fixed to the other end, and the other end is inserted between the outer surface material 190 and the waterproof sheet 180, and a closing piece 119 that closes the opening of the triangular structure 40 adjacent to the exhaust hole 110 is provided. A gap 116 is formed between the lower end edge of the bent piece 118 and the outer surface material 190 to open the air exhausted from the exhaust hole 110 outward.

  Specifically, the upper end of the outdoor side surface 90 of the triangular structure 40 of one triangular structure 40 of the first structure 11 is positioned below the opposed outdoor side surface 80 so that the inner space 100 is separated. An outdoor side surface exhaust unit 112 that opens to the outdoors is formed. The upper end of the waterproof sheet 180 on the outdoor side surface 90 is aligned with the upper end position of the outdoor side surface 90 and the upper end is positioned below the opposing outdoor side surface 80, so that the outdoor side surface A waterproof sheet exhaust 113 is formed that opens from the exhaust 112 toward the outdoor side. The upper end portion of the outer surface material 190 on the waterproof sheet 180 is aligned with the upper end position of the waterproof sheet 180 and the upper end is positioned below the opposing outdoor sheet 80 so that the waterproof sheet exhaust unit 113 can An outer surface material exhaust portion 115 that opens toward the outside is formed. That is, the outdoor side surface exhaust part 112, the waterproof sheet exhaust part 113, and the outer surface material exhaust part 115 form an exhaust hole 110 penetrating between the internal space 100 and the outside. The air in the internal space 100 is formed so as to be discharged from the exhaust hole 110 through the gap 116 to the outside.

Although not particularly illustrated, in the first structure portion 11, the sides as the edge trunk edge communicating means 311 of each edge trunk edge 310 located at the boundary between adjacent forward triangular structures 42 in the same layer The uppermost layer adjacent communication portion that communicates from the inner space 100 of the forward triangular structure 42 to the inner space 100 of the adjacent forward triangular structure 42 in the same layer of the uppermost layer is formed via the edge trunk edge communication groove 312. . The air in the other internal space 100 moves to the exhaust hole 110 provided in one of the five triangular structures 40 through the uppermost layer adjacent communication portion.
In the present embodiment, the exhaust hole 110 described above is formed in one of the five triangular structures 40 of the first structure portion 11, but the present invention is not necessarily limited thereto. For example, similar exhaust holes 110 may be formed in two or more triangular structures 40 of the first structure portion 11.

Further, instead of the above-described exhaust hole 110 or in addition to the above-described exhaust hole 110, the same applies to the triangular structure 40 of the layer structure portion L (for example, the second structure portion 12) below the first structure portion 11. An exhaust hole 110 having a shape may be formed.
As shown in FIG. 7, a base connector 72 is fixed on a foundation 30 made of concrete. The forward triangular structure 42 of the triangular structure 40 of the fifth structure portion 15 as the lowermost layer is fixed to the arm 77 of the base connector 72. An intake hole 120 is provided at the lower end of the forward triangular structure 42 of the fifth structure portion 15 so as to open from the internal space 100 between the outdoor side surface 80 and the outdoor side surface 90 toward the outside. ing. A ventilation member 121 made of polypropylene is formed in the intake intake portion of the intake hole 120. The ventilation member 121 is made of polypropylene with a number of fine minute holes formed in the vertical direction in order to secure the intake capacity and prevent the invasion of insects and rats. Has been. The ventilation member 121 is formed at the lower end of the fifth structure portion 15 of the dome-shaped structure 10 over the entire circumference. The outdoor air that has entered through the air intake hole 120 through the ventilation member 121 rises in the internal space 100 as the ventilation layer 350. The ascending air is discharged to the outside from the exhaust hole 110 through the ventilation layer 350 communicating to the upper layer of the hierarchical structure through the above-described adjacent communication portion 360 and the upper layer communication portion 370.

Note that, on the outdoor side of the forward triangular structure 42 of the fifth structure portion 15, the outdoor side surface 80, the outdoor side surface 90, the waterproof sheet 180, and the outer surface material 190 are concretely below the frame member 50. Is extended below the upper end surface of the foundation 30.
In addition, a heat insulating layer 130, a moisture-proof sheet 381, and an interior finishing material 220 are also formed below the upper end surface of the foundation 30 on the indoor side of the triangular structure 40 as in the case described with reference to FIG.
(Function and effect)
According to the present embodiment, as shown in FIG. 1, the frame member 50 corresponding to each side of the triangle of the triangular structure 40 is connected by the connector 71 as the fixing means 70 at the position of the apex of the triangle. A triangle of the triangular structure 40 is formed. At the same time, the ends of the frame members 50 of other adjacent triangular structures 40 are also connected by the connector 71 as the fixing means 70. Thereby, a plurality of triangular structures 40 are continuously provided.

A frame member 50 provided at a position corresponding to each side of the triangle of each triangular structure 40, and a connector 71 as a fixing means 70 provided at a position corresponding to each vertex of the triangle of each triangular structure 40; The dome-shaped truss skeleton is constructed from the dome-shaped truss skeleton.
According to the present embodiment, as shown in FIG. 2, since the outdoor side surface 80 and the indoor side surface 225 are supported by the reinforcing member 140, the outdoor side surface 80 and the indoor side surface 225 are provided. The deformation is suppressed and the rigidity is increased. As a result, the rigidity of the dome-shaped structure 10 as a whole can be increased.

In the present embodiment, as shown in FIG. 5, an edge trunk edge 310 as a base material is fixed between the edges of the outdoor side surface 80 and the outdoor side surface 90. . For this reason, the edge of the outdoor side surface 90 is prevented from being deformed or damaged by an external force, and the rigidity of the triangular structure is increased. As a result, the rigidity of the dome-shaped structure 10 as a whole is also increased.
In this embodiment, as shown in FIGS. 3 and 5, a large amount of water vapor is supplied to the internal space 100 between the outdoor side surface 80 and the outdoor side surface 90 of the forward triangular structure 42 of the alternating layer structure 20. Even if the air contained in the air enters, the air containing moisture diffuses and moves to the internal space 100 of the inverted triangular structure 41 adjacent to the left and right of the forward triangular structure 42 via the adjacent communication portion 360. Specifically, the air including moisture in the internal space 100 of the forward triangular structure 42 is located on each edge trunk 310 located at the boundary between the adjacent forward triangular structure 42 and the inverted triangular structure 41 in the same hierarchy. It moves to the internal space 100 of the left and right inverted triangular structures 41 via the peripheral edge trunk edge communication groove 312.

  In the present embodiment, as shown in FIG. 3, even if air containing a large amount of water vapor enters the internal space 100 of the inverted triangular structure 41 from the adjacent communication portion 360 of the alternate layer structure portion 20, the upper layer communication portion The air containing moisture diffuses and moves through the inner space 100 of the forward triangular structure 42 adjacent to the upper layer of the inverted triangular structure 41 via the 370. Specifically, the air containing moisture in the internal space 100 of the triangular structure 40 expands due to heat from the outside or the indoor side, increases in volume, and moves upward. In the inverted triangular structure 41, the cross-sectional area increases as the horizontal cross section of the internal space 100 increases. As a result, the air that is going to rise while increasing the volume moves smoothly upward in the internal space 100 of the inverted triangular structure 41 and is also diffused as it moves upward. The air finally reaches the edge trunk edge 310 located on the side where the horizontal cross-sectional area of the inverted triangular structure 41 is the largest (so-called bottom side) and located on the boundary in contact with the upper layer. The reached air passes through the edge trunk edge communication groove 312 of the edge trunk edge 310 and the edge trunk edge communication groove 312 of the edge trunk edge 310 located at the boundary of the upper-order forward triangular structure 42, The forward triangular structure 42 moves into the internal space 100. As a result, the air in the internal space 100 of the inverted triangular structure 41 smoothly moves to the internal space 100 of the upper forward triangular structure 42 via the upper communication portion 370. As a result, the air movement to the upper layer is favorably performed in the alternate layer structure portion 20.

  The adjacent communication portion 360 and the upper layer communication portion 370 described above prevent moisture containing air from staying in the internal space 100 of the specific triangular structure 40 in the dome-shaped structure 10. Therefore, the occurrence of condensation in the internal space 100 of the triangular structure 40 of the dome-shaped structure 10 is suppressed. As a result, the internal space 100 of the triangular structure 40 is kept dry, and the environment of the internal space 100 of the triangular structure 40 is well maintained. Further, even if air containing moisture is present in the indoor space 226 inside the triangular structure 40 and on the indoor side of the outdoor sheet 80, the air is diffused through the internal space 100 of the triangular structure 40. And can be moved. This makes it possible to provide a durable dome-like structure 10. Even when a heat insulating material is used in the triangular structure 40, the inside of the triangular structure 40 is in a dry state, so that the occurrence of condensation is suppressed, thereby preventing moisture from adhering to the heat insulating material. And the deterioration of the heat insulation performance is suppressed.

As shown in FIG. 3, a vertical trunk edge 320 along the longitudinal direction is formed between the outdoor side surface body 80 and the outdoor side surface body 90 inside the triangle of the triangular structure 40. As a result, the deformation of the outdoor side surface 90 inside the triangle of the triangular structure 40 is suppressed, and the rigidity of the outdoor side surface 90 and the outdoor side surface 80 is increased. As a result, the rigidity of the dome-shaped structure 10 as a whole can be increased.
The vertical trunk edge 320 is formed with a vertical trunk edge communication groove 322 that communicates from one small space 143 partitioned by the vertical trunk edge 320 to the other small space 143. For this reason, the small spaces 143 are ventilated through the vertical trunk edge communication grooves 322, and the air in the internal space 100 can freely move. Thereby, the movement of air between the small spaces 143 partitioned by the vertical body edge 320 is not hindered, and a good air flow in the internal space 100 of the triangular structure 40 is maintained.

As shown in FIG. 3, a short top trunk edge 330 is formed between the outdoor side surface 80 and the outdoor side surface 90 near the apex of the triangle of the triangular structure 40. Thereby, the deformation due to the external force of the outdoor side surface 90 near the apex of the triangle of the triangular structure 40 is suppressed, and the rigidity in the vicinity of the apex of the outdoor side surface 90 and the outdoor side surface 80 is increased. As a result, the rigidity of the dome-shaped structure 10 as a whole can be increased.
The top trunk edge 330 is formed with a top trunk edge communication groove 332 that communicates from one small space 143 partitioned by the top trunk edge 330 to the other small space 143. For this reason, the small spaces 143 are ventilated through the top trunk edge communication groove 332, and the air near the apex in the internal space 100 can freely move. Thereby, the movement of air between the small spaces 143 partitioned by the top trunk edge 330 is not hindered, and a good air flow particularly in the vicinity of the apex of the triangle in the internal space 100 of the triangular structure 40 is maintained. .

In order to maintain the rigidity near the apex of the outdoor side surface 90 of the triangular structure 40, when the edge trunk edge 310 is formed to the apex, the narrow area near the apex is composed of 5 or 6 acute angles. The apex portion must be formed by the edge trunk edge 310. The operation of forming the above-mentioned shape in a narrow area is very troublesome. Therefore, the work is facilitated by arranging the short top trunk edge 330 without extending the edge trunk edge 310 to the vicinity of the apex. The top trunk edge 330 having the top trunk edge communication groove 332 maintains the rigidity of the outdoor side surface 90 near the apex and ensures free movement of air.
In the present embodiment, as shown in FIG. 7, outdoor air enters through the ventilation member 121 from the intake hole 120 at the lower end of the triangular structure 40 located in the lowermost layer structure portion L of the hierarchical structure. The air that has entered through the intake holes 120 expands due to a temperature rise caused by sunlight irradiation on the outdoor side, a temperature rise caused by heat of indoor heating, and the like, and the outdoor sheet 80 and the outdoor The inside of the internal space 100 as the ventilation layer 350 between the side surface bodies 90 rises. The ascending air moves from the internal space 100 of the forward triangular structure 42 of the alternating layer structure unit 20 to the internal space 100 of the inverted triangular structure 41 adjacent in the same level via the adjacent communication unit 360. The moved air moves from the internal space 100 of the inverted triangular structure 41 to the internal space 100 of the forward triangular structure 42 adjacent to the upper layer via the upper layer communication portion 370. By repeating this in a plurality of alternating layer structure portions 20 of the hierarchical structure, the air moves to the upper layer, and finally the moved air enters the internal space 100 of the triangular structure 40 of the upper layer structure portion L of the hierarchical structure. Moving. As shown in FIG. 6, the moved air is discharged from the internal space 100 as the ventilation layer 350 of the upper triangular structure 40 through the exhaust hole 110 of the outdoor side surface 90 to the inside of the hood member 111. The discharged air is exhausted to the outdoors through the gap 116 of the hood member 111.

  In this way, an air flow that naturally rises from the intake hole 120 toward the exhaust hole 110 is formed in the internal space 100 as the ventilation layer 350 of the triangular structure 40 via the adjacent communication part 360 and the upper layer communication part 370. Is done. As a result, even when humid air enters the internal space 100 surrounded by the outdoor side surface 80 and the outdoor side surface 90 from the indoor side, the air containing the humidity rises in the ventilation layer 350. The air is efficiently discharged from the exhaust hole 110 to the outside by the air flow. Therefore, water vapor that causes condensation is quickly discharged to the outdoors. As described above, the ventilation layer 350 that generates a natural air flow is formed on the entire surface of the dome-shaped structure 10 in the triangular structure 40, whereby ventilation in the internal space 100 of the triangular structure 40 is promoted. The

As shown in FIG. 5, a heat insulating layer 130 is formed on the indoor side of the outdoor sheet 80. Thus, the ventilation layer 350 is not filled with a heat insulating material, and the entire space in the ventilation layer 350 is used as a space for moving the rising air.
In general, when the heat insulating layer 130 is provided in a part of the air-permeable layer 350, the air-permeable layer 350 can be used for ventilation only in a part of the space where the heat-insulating layer 130 is not provided. Compared with the case where a space for ventilation is provided only in a part of the ventilation layer 350, a large amount of air flow can be generated in the ventilation layer 350 in this embodiment. Thereby, the humid air in the ventilation layer 350 can be efficiently discharged, and the environment inside the triangular structure 40 is further improved.

Further, as shown in FIG. 5, the heat insulating layer 130 is formed on the indoor side of the outdoor sheet 80. For this reason, in the winter season when the outdoor temperature is low, the heat insulating layer 130 is strongly influenced by the air in the indoor side where the temperature is higher than in the interior space 100 close to the outdoors or outdoors. As a result, the heat insulating layer 130 is formed in air having a relatively high temperature and a high saturated water vapor amount as compared with the case where the heat insulating layer 130 is formed in the ventilation layer 350 or the outdoor side of the outdoor side surface 90. As a result, the possibility of dew condensation occurring in the heat insulating layer 130 itself can be reduced. Thereby, the heat insulation performance of the heat insulation layer 130 is maintained in a good state.
As shown in FIG. 5, the moisture-proof layer 380 made of the moisture-proof sheet 381 is provided on the indoor side of the outdoor sheet 80 to prevent moisture from the indoor side from entering the triangular structure 40. As a result, the internal space 100 of the triangular structure 40 is further maintained in a dry state, and the environment of the internal space 100 of the triangular structure 40 is maintained well, and a more durable dome-shaped structure 10 can be provided. Become.

As shown in FIG. 5, since the moisture-proof layer 380 is provided on the indoor side of the heat insulating layer 130, it is possible to suppress moisture on the indoor side from reaching the heat insulating layer 130. As a result, a decrease in heat insulation performance is suppressed, and good heat insulation performance can be maintained.
(Second Embodiment)
As shown in FIG. 8, the triangular structure 40 according to the second embodiment is obtained by fixing three frame members 50 at positions corresponding to the sides of each triangle. In the same manner as in the first embodiment, the outdoor structure 80 is formed on the surface of the triangular structure 40 located on the outdoor side, and the trunk edge 300 is formed on the outdoor side of the outdoor structure 80. An outdoor side surface 90 is formed on the outdoor side of the trunk edge 300. The triangular structure 40, the outdoor side surface body 80, the outdoor side surface body 90, and the trunk edge 300 form a triangular structure panel 160 having a triangular plan view. A moisture-proof sheet 381 and an interior finishing material 220 as an indoor side surface body 225 are formed on the surface of the triangular structure 40 located on the indoor side.

In the present embodiment, a dome-like dome-like structure 10 is formed by connecting a plurality of triangular structure panels 160 having a triangular plan view to each other without gaps.
In the dome-like structure 10 according to the present embodiment, a triangular structure panel 160 having a triangular plan view can be formed in advance by a factory or the like. Therefore, such a triangular structure panel 160 can be assembled by connecting together the ones in the integrated state by field work. As a result, on-site work can be greatly simplified and construction can be performed in a short time.
Here, the ends of the three frame members 50 of the triangular structure panel 160 are fixed by fastening members such as nails or screws, although not particularly shown. Note that the ends of the frame member 50 may be joined to each other with an adhesive.

Adjacent triangular structure panels 160 are fixed by fastening members such as nails or screws, although not particularly shown. Note that the adjacent frame members 50 may be joined together using an adhesive.
In the present embodiment, the frame members 50 of adjacent triangular structure panels 160 are fixed in contact with each other. Further, inside the indoor space 226 between the outdoor side surface 80 and the indoor side surface 225, there is a reinforcing member 140 composed of a vertical reinforcing member 141 and a horizontal reinforcing member 142 similar to those in the first embodiment. Is formed.
Similar to the first embodiment, an internal space 100 is formed between the outdoor side surface 80 and the outdoor side surface 90 inside the triangular structure panel 160. The trunk edge 300 provided on the outdoor side of the outdoor sheet 80 is formed with the edge trunk edge 310, the vertical trunk edge 320, and the top trunk edge 330 similar to those of the first embodiment shown in FIG. Each trunk edge 300 is formed with the same communication means 301 as in the first embodiment. That is, each trunk edge 300 has a peripheral trunk edge communication groove 312 as a peripheral trunk edge communication means 311 similar to that of the first embodiment, a vertical trunk edge communication groove 322 as a vertical trunk edge communication means 321, Further, a top trunk edge 330 as the top trunk edge communication means 331 is formed. In the present embodiment, the adjacent communication portion 360 and the upper layer communication portion 370 similar to those of the first embodiment are formed in the alternating layer structure portion 20 similar to that of the first embodiment. In the present embodiment, exhaust holes 110 and intake holes 120 similar to those in the first embodiment are formed (see FIGS. 6 and 7). In the dome-shaped structure 10 according to the present embodiment, a ventilation layer 350 that communicates from the intake hole 120 to the exhaust hole 110 via the adjacent communication part 360 and the upper layer communication part 370 is formed. The ventilation layer 350 generates a natural air upward flow and has good ventilation performance, which is the same as that of the first embodiment.

10 Dome structure L layer structure
11 1st structure part 12 2nd structure part
13 Third structure 14 Fourth structure
15 Fifth structure part 20 Alternating layer structure part
30 foundation 40 triangular structure
41 inverted triangle structure 42 forward triangle structure
43 Upper layer opening 50 Frame member
70 Fixing means 71 Connector
72 Base connector 73 Beam connector
74 5 arm connector 75 6 arm connector
76 Hub 77 Arm
78 Reinforcing flat plate 80 Outdoor surface
90 Outdoor side surface 100 Internal space
110 Exhaust hole 111 Hood member
112 Exhaust section of outdoor side body 113 Exhaust section of waterproof sheet
115 Outer surface material exhaust 116 Clearance
117 Fixed piece 118 Folded piece
119 Blocking piece 120 Air intake hole
121 Ventilation member 130 Thermal insulation layer
140 Reinforcement member 141 Vertical reinforcement member
142 Lateral reinforcement 143 Small space
160 Triangular panel 180 Tarpaulin
190 Outer surface material 220 Interior finishing material
221 Corner finishing material 225 Indoor side surface
226 Indoor space 230 Fastener
300 trunk 301 communication means
310 Edge trunk edge 311 Edge trunk edge communication means
312 Edge trunk edge communication groove 320 Vertical trunk edge
321 Longitudinal edge communication means 322 Longitudinal edge communication groove
330 Top trunk edge 331 Top trunk edge communication means
332 Top trunk edge communication groove 350 Ventilation layer
360 Adjacent communication section 370 Upper layer communication section
380 Moisture-proof layer 381 Moisture-proof sheet

Claims (7)

Consists of three frame members provided at positions corresponding to the sides of the triangle, and the ends of the frame members are connected by fixing means provided at positions corresponding to the apexes of the triangle. A plurality of triangular structures are formed in a dome shape by connecting a plurality of three-dimensionally without gaps,
A plurality of layered structure portions formed in an annular shape by connecting the triangular structures without gaps are formed in a layered structure,
In the triangular structure,
An outdoor side planar body covering a surface located on the outdoor side of the frame member;
A marginal trunk edge fixed as a base material on a surface located on the outdoor side of the outdoor planar body along the edge of the triangle;
An outdoor side surface body is formed that is fixed to a surface located on the outdoor side of the marginal trunk edge and covers the outdoor planar body with the marginal trunk edge sandwiched between the outer circumferential plane body And
A communication groove whose surface is recessed in a cross-sectional concave shape is formed in the marginal body edge as a communication means that communicates from the internal space between the outdoor side surface body and the outdoor side surface body toward the adjacent triangular structure side. And
The hierarchical structure includes the triangular structure that is in contact with the upper layer only at the apex of the triangle (hereinafter, referred to as “forward triangular structure”) and the triangular structure that is in contact with the upper layer with the sides of the triangle as the layer structure portion. A body (hereinafter referred to as an “inverted triangular structure”) and alternating layer structure portions alternately arranged on the circumference,
In the alternate layer structure portion, the internal space of the forward triangular structure is formed via the communication means of the peripheral trunks located at the boundary between the adjacent forward triangular structure and the inverted triangular structure. A dome-like structure characterized in that an adjacent communication portion that communicates with the internal space of the inverted triangular structure adjacent to each other in the same layer is formed.   In the alternate layer structure portion, the inverted triangular structure body is connected to the upper triangular triangle structure body that is in contact with the inverted triangular structure body via the communication means of the peripheral trunk edges. 2. The dome-like structure according to claim 1, wherein an upper layer communication portion that communicates from the internal space to the internal space of the forward triangular structure located in the upper layer is formed. On the surface located on the outdoor side of the outdoor planar body, a vertical trunk edge is formed along the vertical direction inside the triangle,
In the internal space of the triangular structure, a plurality of small spaces partitioned by the vertical trunk edge are formed,
3. The communication device according to claim 1, wherein the vertical body edge is formed with a communication unit that communicates from one small space partitioned by the vertical body edge to the other small space. Domed structure. A triangular structure panel having a triangular plan view is formed having at least the triangular structure, the outdoor side surface, the outdoor side surface, and the edge trunk edge,
The dome-like structure according to any one of claims 1 to 3 , wherein a plurality of the triangular structure panels are three-dimensionally connected without gaps to form a dome shape. The outdoor side surface of the triangular structure located in the upper layer structure portion is provided with an exhaust hole that is open to the outdoors from the internal space,
At the lower end of the triangular structure located in the lowermost layer structure portion, an intake hole that is open to the outdoors from the internal space is provided,
3. The dome-like structure according to claim 2, wherein the triangular structure includes a ventilation layer communicating from the intake hole to the exhaust hole via the adjacent communication portion and the upper layer communication portion. . The dome-like structure according to any one of claims 1 to 5 , wherein a heat insulating layer made of a heat insulating material is formed on the indoor side of the outdoor side planar member. The dome-like structure according to any one of claims 1 to 6 , wherein a moisture-proof layer made of a moisture-proof sheet is formed on the indoor side of the outdoor-side sheet.

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