KR102692056B1 - turnel or dome type's pipe structure and construction method of it - Google Patents

Abstract

In order to solve the above-described problem, the tunnel or dome-shaped pipe structure of the present invention includes a foundation member (10) whose lower part is embedded and fixed in the ground; A pillar member (20) whose lower part is connected to the upper part of the base member (10) and extends vertically upward; a lower horizontal member (30) extending horizontally to connect the upper part of the adjacent pillar member (20); a plurality of upper horizontal members (40) spaced apart from the lower horizontal member (30) and extending in a horizontal direction in parallel with the lower horizontal member (30); a one-way inclined member (50) whose lower part is connected to the upper part of the pillar member (20) and which extends obliquely in one direction; It is composed of a; the other inclined member 60, the lower part of which is connected to the upper part of the pillar member 20 and obliquely extending in the other direction, and is composed of the pillar member 20, the lower horizontal member 30, and the upper horizontal member. The member 40, the one-way inclined member 50, and the other inclined member 60 are made of pipes, and the pipes are pressurized at the points where the members (20, 30, 40, 50, and 60) intersect to form a flat shape. Plate-shaped portions 100 are formed, and bolt fastening holes 110 are formed in each plate-shaped portion 100, so that the plate-shaped portions 100 that cross each other are connected by bolting while facing each other, and the pillar member (20) is characterized in that it is connected by fitting and bolting to the base member (10) in a sliding manner.
According to the present invention, rather than connecting unit members of a certain length, a plurality of plate parts are formed at regular intervals on a long elongated member, and these plate parts are bolted together while facing each other, thereby improving structural stability and facilitating construction. It can be done. In addition, it is possible to overcome construction difficulties caused by the accumulation of errors between bolt holes and bolts. In addition, by fitting the foundation member and the column member in a sliding manner, even when the column members are at different levels, they can be smoothly leveled by the structural load on the top of the column member and construction can be facilitated.

Description

Tunnel or dome type's pipe structure and construction method of it {turnel or dome type's pipe structure and construction method of it}

The present invention relates to a tunnel or dome-shaped pipe structure in which a plurality of pipes are interconnected to form a frame, such as an agricultural greenhouse, and a construction method thereof. Rather than connecting unit length members through connectors, the present invention relates to the intersection of long pipes. It relates to a tunnel or dome-shaped pipe structure that has high structural stability and ease of construction by connecting points through bolts.

Most existing tunnel-type pipe structures, such as agricultural greenhouses, mainly use parts made of thin steel wire or wire for cross-connection between pipes forming the frame.

For example, "Resin-coated greenhouse pipe fixture" (Korea Registered Utility Model Publication No. 20-0452681, Patent Document 1) discloses a connector in which a steel wire is partially banded round to match the shape of the pipes crossing.

These connectors have improved constructability so much that they are actually used in the construction of many greenhouses.

However, when the strong snow load or wind load introduced in Patent Document 1 is applied, the problem of slipping and collapse occurs.

In particular, in recent years, unexpected strong winds and snowfall have occurred due to climate change, and as a result, cases of greenhouses collapsing due to pipes slipping in connectors are increasing.

Meanwhile, existing tunnel-type pipe structures, such as greenhouses, have a structure with insufficient resistance to concentrated loads as the upper load is supported by a frame connected in a square shape.

The existing tunnel-type pipe structure is a specially manufactured three-dimensional truss structure (a series of three-dimensional truss structures made up of triangles may appear similar to the principle of a geodesic dome, but the geodesic flat triangle structure and the general three-dimensional truss structure are different in architectural structure). Except for the applied part (which requires interpretation and distinction of terminology or form), it is basically manufactured with a width of 6 to 8 m, and even with a specially manufactured truss structure, the reality is that it is difficult for the width to exceed 15 m. am.

Typical interlocking tunnel-type structures (including agricultural greenhouses) are connected at a distance of 6 to 8 m, and in the event of a natural disaster (heavy snow/typhoon/earthquake), the interconnected parts receive concentrated structural load, causing the basic structural resistance of the members to be lost. will be.

Interlocking tunnels in “Reinforcement structures for greenhouses” (Korean Patent Publication No. 10-1742479, Patent Document 2), “Green house frames with customized trusses” (Korean Patent Publication No. 10-2455278, Patent Document 3), etc. Many technological approaches have been made to the mold pipe structure, but they are not showing much effect.

In addition, the existing tunnel-type pipe structure supports the structure by erecting columns 6 to 8 m wide, so even though it is an interlocking structure, the total area can be considered large. However, because pipe columns are installed to support the load every 6 m or so. There were difficulties in moving or rotating large mechanical equipment.

In addition, existing tunnel-type pipe structures have a height limit of about 3 to 4 m. Due to recent global warming, it is difficult to accommodate various heights and widths in the process of cultivation and distribution of tall agricultural and ornamental tropical crops, and vertical Application of multi-stage agriculture such as palm farming is also bound to be limited.

Accordingly, in order to overcome the limitations of the tunnel-type pipe structure described above, a structure incorporating the theory of a triangular geodesic dome has recently been proposed.

However, errors found in the bolt fastening method in a typical geodesic dome structure can lead to structural collapse, and there is an urgent need to introduce technology to minimize these errors.

For example, in "Geodesic dome tent and method of manufacturing the same" (Korean Patent Publication No. 10-2011-0006170, Patent Document 4), the dome frame is composed of unit pipes, and each unit is made up of unit pipes, as shown in Figure 2. The pipes were gathered together to create a single binding point.

At this time, a bolt fastening hole of a certain size is formed in each pipe. To fasten a bolt, the outer diameter of the bolt must be larger than the outer diameter of the bolt to be inserted. It is inseparable that errors occur depending on the size of the bolt hole and the size of the bolt. It's a relationship.

As such, errors occurring between the bolt holes and bolt sizes at each connection point of the unit pipes result in significant errors when looking at the structure as a whole, so even skilled technicians are bound to encounter significant difficulties in assembling.

This problem is also found in “green house with three-dimensional truss structure” (Korean Patent Publication No. 10-2176945, Patent Document 5).

Looking at FIG. 3, holes for fastening bolts are formed at both ends of the members connected to form the triangle shown in Patent Document 5. Assuming that the error between the bolts and holes is 1 mm, 20 members are connected and a concentrated load is applied in one direction. If this occurs, an error that increases or decreases the length of 20mm occurs.

Meanwhile, the upper structure is completed by connecting unit pipe members on top of the column members that form the basis of conventional tunnel-type pipe structures, fixed to the ground, due to the error between the bolt hole and bolt as described above. Accordingly, the connection points between members cannot be completely fixed from the beginning, and provisional assembly is performed. After the overall provisional assembly is completed, the connection points between members are fully assembled (completely tightening bolts and nuts), making the assembly work very cumbersome. there is.

In particular, the foundation members had to be connected so that they were all level, otherwise it would be difficult to accurately maintain the overall level, resulting in loss of balance.

In addition, when the connection between the foundations is also made of a unit connecting member, there is a problem in that it is impossible to suppress the phenomenon caused by the width direction load or the longitudinal load due to the above-mentioned error.

KR 20-0452681 (2011.03.04) KR 10-1742479 (2017.05.26) KR 10-2455278 (2022.10.12) KR 10-2011-0006170 (2011.01.20) KR 10-2176945 (2020.11.04)

The tunnel or dome-shaped pipe structure of the present invention is intended to solve the problems occurring in the prior art as described above. Rather than connecting unit members of a certain length, a plurality of plate-shaped portions are formed at regular intervals on a long extending member. The purpose is to increase structural stability and facilitate constructability by bolting these plate sections in a butt-to-face state.

In addition, by allowing the foundation member and the column member to be fitted together in a sliding manner, even when the levels of the column members are different, they can be smoothly leveled by the structural load on the top of the column member and facilitate construction.

In order to solve the above-mentioned problem, the tunnel or dome-shaped pipe structure of the present invention comprises: a foundation member (10) whose lower part is buried in the ground and fixed; a column member (20) whose lower part is connected to the upper part of the foundation member (10) and extends vertically upward; a lower horizontal member (30) which is horizontally extended to connect the upper part of an adjacent column member (20); a plurality of upper horizontal members (40) which are spaced apart from the lower horizontal member (30) and which extend horizontally parallel to the lower horizontal member (30); a one-way inclined member (50) whose lower part is connected to the upper part of the column member (20) and which extends inclined in one direction; It is composed of a side-slanting member (60) that is extended in the other direction while being connected to the upper portion of the column member (20), and the column member (20), the lower horizontal member (30), the upper horizontal member (40), the side-slanting member (50), and the other-slanting member (60) are made of pipes, and at the point where the members (20, 30, 40, 50, 60) intersect, a plate-shaped portion (100) is formed in which the pipe is pressurized to form a flat shape, and a bolt fastening hole (110) is formed in each plate-shaped portion (100) so that the plate-shaped portions (100) that intersect each other are bolt-fastened while facing each other, and the column member (20) is characterized in that it is connected by being bolt-fastened while being fitted in a sliding manner with respect to the foundation member (10).

In the above configuration, a bolt fastening hole 12 is formed on the outside of the base member 10 for bolt connection with the pillar member 20, and the pillar member 20 is formed by a bolt fastening elongated up and down. A long hole 21 is formed to enable bolt fastening by adjusting the insertion depth of the base member 10 and the pillar member 20.

In the above configuration, a plurality of cut portions 15 are formed downward from the top of the base member 10 to a certain length, and the base member 10 separated by the cut portions 15 is formed. The wall surface is bent outward to form a guide portion 16 in which the upper portion of the hollow portion 11 has an inner diameter gradually larger than the lower portion.

In the above configuration, the structure is composed of a tunnel-type pipe structure, and the two ends of the lower horizontal members 30 facing each other are connected, but are curved and banded to form an arch, and the lower horizontal members 30 , a plate-shaped portion 100 provided with the bolt fastening hole 110 is formed at a portion where any one of the upper horizontal member 40, the one-way inclined member 50, and the other inclined member 60 intersect. It is characterized in that it is further provided with an end finishing member 70 that is bolted to the member.

The construction method of a tunnel or dome-shaped pipe structure of the present invention includes a foundation installation step of embedding and fixing a plurality of foundation members 10 having a hollow interior in the ground; A plate-shaped portion 100 is formed in a flat shape by pressurizing the upper part, and a column member 20 made of a pipe in which a bolt fastening hole 110 is formed in the plate-shaped portion 100 is prepared to form a column member ( A pillar installation step of inserting the lower part of 20) into the upper part of the foundation member 10; The upper parts of the adjacent pillar members 20 are horizontally connected using the lower horizontal member 30, and the lower ends of the one-way inclined member 50 and the other inclined member 60 are connected to the pillar member 20 and the lower horizontal member ( 30) are connected to each other obliquely in one direction and the other direction, and the upper horizontal member 40 is parallel to the lower horizontal member 30 and connected to the one-way inclined member 50 and the other inclined member 60. Forming an upper skeleton, the lower horizontal member 30, upper horizontal member 40, one-way inclined member 50, and other inclined member 60 are made of pipes, and the members (20, 30, 40, 50) , 60) are formed at the point where the pipes are pressurized to form a flat shape, and bolt fastening holes 110 are formed in each plate part 100, so that the plate parts intersect each other. An upper frame assembly step of bolting (100) together using assembly bolts 120 and assembly nuts 121; A horizontal adjustment step of fixing the pillar member 20 and the foundation member 10 by bolting them together while adjusting the depth at which the pillar member 20 is inserted into the base member 10 so that the lower horizontal member 30 is level; It is composed including.

According to the present invention, rather than connecting unit members of a certain length, a plurality of plate-shaped portions are formed at regular intervals on a long extending member, and these plate-shaped portions are bolted together in a butt-to-face state to increase structural stability and facilitate constructability. It can be done.

More specifically, the connection between members is fastened using a bolt method rather than a wire-type one-touch connector, and structural stability can be doubled by utilizing long extended members rather than connecting short unit members.

In addition, it is possible to overcome construction difficulties caused by the accumulation of errors between bolt holes and bolts.

In addition, by fitting the foundation member and the column member in a sliding manner, even when the column members are at different levels, they can be smoothly leveled by the structural load on the top of the column member and construction can be facilitated.

1 is a diagram showing an example of a connector used in a conventional tunnel-type pipe structure.
Figure 2 is a diagram showing an example of bolt connection through unit units when connecting a conventional geodesic dome.
Figure 3 is a diagram showing the connection state between members through unit units in a conventional tunnel-type pipe structure.
Figure 4 is a perspective view showing a pipe structure according to the present invention.
Figure 5 is an exploded perspective view showing the connection state of the main members in Figure 4.
Figure 6 is a perspective view showing the connection state of the pillar and foundation member in Figure 4.
Figure 7 is an exploded perspective view showing the connection state of the column and foundation member in Figure 4.
Figure 8 is a cross-sectional schematic diagram showing the construction state when the construction depth of the foundation is different in the present invention.
Figure 9 is a cross-sectional schematic diagram showing an example consisting of multiple skeletons in the present invention.
Figure 10 is a perspective view showing another example of a base member in the present invention.

Hereinafter, the tunnel or dome-shaped pipe structure of the present invention will be described in detail through the attached drawings.

The tunnel or dome-shaped pipe structure of the present invention largely includes a foundation member (10), a column member (20), a lower horizontal member (30), an upper horizontal member (40), a one-way inclined member (50), and an other inclined member (60). It consists of:

The foundation member 10, which is a component of the present invention, is fixed at the bottom by being buried in the ground. A concrete foundation is connected to the bottom and buried in the ground, or the lower part is pointed and buried in the ground as shown in FIGS. 6 and 7. do.

This base member 10 is fitted and coupled to the pillar member 20 in a sliding manner. For this purpose, as shown in the drawing, a hollow tube-shaped hollow part 11 is formed, so that the pillar member 20 is formed in the hollow part. It is configured so that it can be inserted into (11).

In addition, a bolt fastening hole 12 is formed on the outside of the base member 10 for bolt connection with the pillar member 20.

In the drawing, reference symbol 13 is a column foundation connecting bolt 13 for bolting the column member 20 and the foundation member 10, and reference symbol 14 is a nut 14.

Meanwhile, in the construction of a tunnel or dome-shaped pipe structure according to the present invention, the upper structure is installed on the foundation member 10 while the foundation members 10 are installed on the ground and the upper members of the foundation member 10 are assembled. A connecting construction method can also be adopted.

In this case, the upper structure is connected to the foundation member 10 using a crane. In order to ensure that the pillar member 20 of the upper structure can be smoothly inserted into the foundation member 10, as shown in Figure 10, the foundation member 10 is connected to the upper structure. Two or more incisions 15 are formed by cutting downward from the top of the member 10 to a certain length, and the wall surface of the base member 10 separated by the incisions 15 is banded outward to form a hollow portion. The upper part of (11) is composed of a guide part 16 whose inner diameter is gradually larger than the lower part, so that the pillar member 20 can be easily inserted.

As shown in Figures 6 and 7, the pillar member 20, which is a component of the present invention, is connected at its lower part to the base member 10 and extends vertically upward.

Looking at Figures 6 and 7, the column member 20 is made of a hollow tube (pipe), and on the sides facing each other, bolts are fastened to be bolted to the foundation member 10 through the column foundation connection bolt 13. A long hole 21 is formed.

The bolt fastening hole (21), unlike the bolt fastening hole (12), is characterized in that it is elongated up and down.

As shown in FIG. 8, when the insertion depth of the foundation member 10 into the ground is different or the ground surface is inclined and the bolt fastening hole 12 of the foundation member 10 adjacent to both sides is not level, there is no need to level it. Even without holding work, it is possible to fix the pillar member 20 and the foundation member 10 to each other while ensuring that the heights of adjacent pillar members 20 are the same.

At this time, the bolt fastening hole 12 and the bolt fastening hole 21 may be formed on opposite members.

Meanwhile, a plate-shaped portion 100 is formed on the upper part of the pillar member 20 to form a flat plate shape by being pressed by a press, and a bolt fastening hole 110 is formed in the plate-shaped portion 100 to secure the assembly bolt 120. And it is configured to be connected to the lower horizontal member 30, the one-way inclined member 50, and the other inclined member 60 through the assembly nut 121.

The lower horizontal member 30, which is a component of the present invention, extends horizontally to connect the upper parts of adjacent pillar members 20, as shown in FIGS. 6 and 7.

Like the pillar member 20, this lower horizontal member 30 is made of a circular pipe. Like the pillar member 20, the pipes are pressurized with a press at regular intervals to form flat plate-shaped portions 100 at regular intervals. In addition, each plate portion 100 is formed with a bolt fastening hole 110 for installing the assembly bolt 120 and the assembly nut 121, so that the bolt is abutted against the plate portion 100 of the pillar member 20. are combined.

In the case of a tunnel-type pipe structure, the lower horizontal member 30 forms a straight line as shown in the drawing, and in the case of a dome-type pipe structure, it takes a circular shape.

The upper horizontal member 40, which is a component of the present invention, is composed of a plurality of pieces spaced apart from the lower horizontal member 30 and extending in the horizontal direction parallel to the lower horizontal member 30.

This upper horizontal member 40, like the lower horizontal member 30, has plate-shaped portions 100 with bolt fastening holes 110 formed at regular intervals, so that the members intersecting each other, the assembly bolt 120, and the assembly It is configured to be fastened through a nut (121).

The one-way inclined member 50, which is a component of the present invention, extends obliquely in one direction with its lower part connected to the upper part of the column member 20, and is bent in a curved shape to form a tunnel or dome-shaped framework.

At this time, the inclined angle with respect to the pillar member 20 is most preferably 60 degrees.

In addition, the one-way inclined member 50, like the lower horizontal member 30 and the upper horizontal member 40, is a member in which plate-shaped portions 100 with bolt fastening holes 110 are formed at regular intervals and intersect each other. It is configured to be fastened through the assembly bolt 120 and the assembly nut 121.

The other inclined member 60, which is a component of the present invention, is also connected to the upper part of the column member 20 and extends obliquely in the other direction, and is curved and bent to form a tunnel or dome-shaped framework.

At this time, the inclined angle with respect to the pillar member 20 is most preferably 60 degrees.

In addition, the other inclined member 60, like the lower horizontal member 30 and the upper horizontal member 40, is a member in which plate-shaped portions 100 with bolt fastening holes 110 are formed at regular intervals and intersect each other. It is configured to be fastened through the assembly bolt 120 and the assembly nut 121.

The one-way inclined member 50 and the other-side inclined member 60 may have various bending curvatures depending on the design, and in some cases, may be formed by bending at a predetermined point.

On the other hand, in the case of a tunnel-type pipe structure rather than a dome as shown in the drawing, two column members 20 on the end sides facing each other in the width direction are interconnected at both ends in the longitudinal direction of the structure, and the ends are curved and banded. A finishing member 70 may be further provided.

As shown in FIG. 6, a plurality of plate-shaped portions 100 with bolt fastening holes 110 are formed in the end finishing member 70, and various intersecting members, assembly bolts 120, and assembly nuts 121 are formed. It is made to be concluded through.

In the above configuration, multiple tunnel or dome-shaped pipe structures may be formed.

In this case, as shown in FIG. 9, in a state where the plate portions 100 of the members forming the inner frame and the outer frame are facing each other, the assembly bolts 120 are attached to the plate portions 100 of the connecting portions of each frame. They are each penetrated in opposite directions, and each assembly bolt 120 is fastened with a long tubular connecting nut 122 having a thread formed on the inner peripheral surface, and a connecting bolt 123 having a thread formed on the outer peripheral surface is connected to the two assembly bolts 120. It is also possible to form a multiple structure by being screwed inward to the connection nut 122.

In the above configuration, the plurality of plate-shaped portions 100 formed on each member are not formed only in the same direction on the cross-section of each member, and are pressed at appropriate points to suit various construction environments such as rounded bending curvature and inclination angle. It can be processed and formed.

The structure of the above configuration does not utilize short unit members, but the one-way inclined member 50, the other inclined member 60, the lower horizontal member 30, and the upper horizontal member 40 extend from one end of the structure to the other end. , the slipping phenomenon that occurs in one-touch connectors does not occur, and the connection between members is firmly established, and the area surrounded by the members is roughly triangular, so structural stability is high, preventing damage from natural disasters such as snow load and wind load. It will be possible to reduce it.

Construction of the tunnel or dome-shaped pipe structure of the above configuration can proceed as follows.

1. Basic installation stage

The foundation member 10 is buried and fixed in the ground according to the designed position.

2. Column installation stage

The lower part of the pillar member 20 is inserted into the upper part of the base member 10.

At this time, bolt connection is not performed.

3. Upper skeleton assembly stage

The lower horizontal member 30 is horizontally connected to the upper part of the adjacent pillar member 20, and the lower ends of the one-way inclined member 50 and the other inclined member 60 are connected to the pillar member 20 and the lower horizontal member 30. ) are connected obliquely in one direction and the other direction, respectively, and the upper horizontal member 40 is parallel to the lower horizontal member 30 and connected to the one-way inclined member 50 and the other inclined member 60 to form the upper Forms the skeleton.

4. Leveling stage

The pillar member 20 and the foundation member 10 are fixed by bolting while adjusting the depth at which the pillar member 20 is inserted into the base member 10 so that the lower horizontal member 30 is horizontal.

Compared to the method of constructing a tunnel-type pipe structure using existing connectors or the construction method using unit members, the above construction method differs from the existing construction method because three members are crossed and bolted to each other at the point where six lines intersect. By comparison, difficulties in construction and structural instability caused by the accumulation of errors between bolt holes and bolts can be resolved.

On the other hand, a method of connecting the pillar member 20 to the upper frame and attaching the pillar member 20 to the base member 10 using equipment such as a crane and fixing it with bolts may be applied.

This method can allow for more efficient construction within the range that allows for the use of equipment for transportation and lifting.

In the above description, the drawings are merely an example for understanding the present invention.

In other words, the present invention allows all parts of a tunnel or dome-shaped structure to be expandable in any direction, left, right, up and down (length, width), like tessellation in geometric mathematics, through a module based on an equilateral triangle with the same length.

In addition, it is not limited to the existing 6m width, and can be freely designed, manufactured, and constructed in multiples of 6m depending on site conditions.

Through this, the existing agricultural greenhouse to cover a width of 30 m was installed by connecting six tunnel-type structures, but in the present invention, it is possible to design, manufacture, and install a structure that can support the load without pillars for a width of 30 m.

In addition, depending on the height of the pillar member 20, it is possible to construct to a high height without being restricted by the height of the structure, making it possible to apply it to multi-stage agriculture such as a vertical farm, and to waste treatment plants, recycling centers, sports centers, etc. that require a sufficient height. It can be applied to various facilities such as event venues.

10: Foundation member 11: Hollow part
12: Bolt fastener 13: Column foundation connection bolt
14: nut 15: cutout
16: guide part 20: pillar member
21: bolt fastening tool 30: lower horizontal member
40: upper horizontal member 50: one-way inclined member
60: Other inclined member 70: End finishing member
100: plate top 110: bolt fastening hole
120: assembly bolt 121: assembly nut
122: connection nut 123: connection bolt

Claims (5)

In a tunnel or dome-shaped pipe structure,
A foundation member (10) whose lower part is buried and fixed in the ground;
A pillar member (20) whose lower part is connected to the upper part of the base member (10) and extends vertically upward;
a lower horizontal member (30) extending horizontally to connect the upper part of the adjacent pillar member (20);
a plurality of upper horizontal members (40) spaced apart from the lower horizontal member (30) and extending in a horizontal direction in parallel with the lower horizontal member (30);
a one-way inclined member (50) whose lower part is connected to the upper part of the pillar member (20) and which extends obliquely in one direction;
It is composed of a; other inclined member 60, the lower part of which is connected to the upper part of the column member 20 and obliquely extending in the other direction,
The pillar member 20, the lower horizontal member 30, the upper horizontal member 40, the one-way inclined member 50, and the other inclined member 60 are made of pipes, and the members (20, 30, 40, 50) , 60) are formed at the point where the pipes are pressurized to form a flat shape, and bolt fastening holes 110 are formed in each plate part 100, so that the plate parts intersect each other. (100) are connected by bolting while facing each other,
The pillar member 20 is connected by sliding and bolting to the base member 10,

A bolt fastening hole 12 is formed on the outside of the base member 10 for bolt connection with the pillar member 20,
The pillar member 20 is formed with a bolt fastening hole 21 extending vertically,
It is configured to enable bolt fastening by adjusting the insertion depth of the foundation member 10 and the column member 20,

A plurality of cut portions 15 are formed downward from the top of the base member 10 to a certain length,
The wall surface of the base member 10 separated by the incision 15 is bent outward to form a guide portion 16 in which the upper portion of the hollow portion 11 has an inner diameter gradually larger than the lower portion,

The structure consists of a tunnel-type pipe structure,
Both ends of the lower horizontal members 30 facing each other are connected, but are curved and banded to form an arch, and the lower horizontal member 30, the upper horizontal member 40, the one-way inclined member 50, and the other inclined member are formed. A plate-shaped portion 100 having the bolt fastening hole 110 is formed at a portion where one of the members 60 intersects, and an end finishing member 70 is bolted to the intersecting member. Characterized by
Tunnel or domed pipe structure. delete delete delete delete