JP2762133B2 - How to build a large architectural space underground - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Industrial Field of the Invention The present invention mainly relates to a large-scale basement having a floor scale of 200 m
Up to 0m ² above are carried out for the purpose of creating a large-scale building large space, a method for the construction of building large space of deep underground.

2. Description of the Related Art Conventionally, as a technique for constructing an underground space, a digging method, a shield method, and the like are generally implemented.

The excavation method first excavates a part corresponding to the outer peripheral wall of the underground space from the underground, inserts reinforcing steel into the excavated part, casts concrete, constructs the underground wall, and then removes the ground surrounded by the underground wall Excavation method.

In the shield method, a strong cylindrical steel shell called a shield machine is pushed into the ground, the ground in front of the part protected by this steel shell is excavated, and the rear part is almost the same as a cylindrical steel shell. This is a method of assembling a ring-shaped lining (segment) to protect the already excavated tunnel space, and constructing a tunnel by repeating the procedure of moving the shield machine forward by taking a reaction force to this lining. .

As a special application technology of the shield method,
The method of constructing an underground cavity described in Japanese Patent Publication No. 64-43699 discloses a method of constructing a shaft from the ground, starting a shield machine from the lower end of the shaft, and constructing an annular or spiral shield tunnel. The inside of the tunnel section is filled with concrete and reinforced, and the inside ground surrounded by the underground outer wall frame constructed in this way is excavated to form a large cavity.

Problems to be solved by the present invention I) In the case of the above-mentioned excavation method, an underground space cannot be constructed under an existing building on the ground. In addition, there is a technical limit in construction accuracy to excavate the underground wall from the ground,
When the depth of the underground is deep, it is difficult to maintain accurate verticality. In addition, there is collapse of earth and sand on the way, so at most 30m underground
It can be constructed only to a certain depth.

II) In case of shield method, 50m under the existing building
It is possible to build tunnels to greater depths. However, the current shield tunnel can only construct a tunnel space with a cross-sectional diameter of at most 10 m. Therefore, it cannot be used for the purpose of constructing a large underground space with a floor area of 2000 m ² or more, and these points are issues to be solved.

III) Next, it is recognized that the method of constructing an underground cavity described in the above-mentioned Japanese Patent Application Laid-Open No. 64-43699 is a groundbreaking technical idea that foresees the feasibility of a large underground large space. .
However, the procedure for building the shield tunnel and completing the shield tunnel in the outer wall frame and its reliability, and the specifics of how to use the formed underground large cavity as an effective space for humans are poorly specific. I must say. For example, simply filling concrete in the cross section of an annular or spiral shield tunnel is not safe because it is difficult to expect sufficient strength and rigidity against earth pressure and groundwater pressure. In addition, creating a hollow space under the ground is not the ultimate purpose, but how to create the hollow space in a reasonably useful architectural space should be the ultimate purpose, so these issues still need to be solved. You have to say.

Means for Solving the Problems As a procedure for solving the problems of the prior art, a method for constructing an architectural large space in a deep underground according to the present invention is as follows. A vertical shaft 1 is constructed, and a large-diameter shield tunnel 2 is constructed horizontally from the vertical shaft 1 along the top of the planned outer peripheral wall of the underground architectural large space, and a surface surrounded by the large-diameter shield tunnel 2 Constructing a large number of substantially horizontal small-diameter shield tunnels 3 in parallel, and constructing a continuous underground wall 4 directly below the large-diameter shield tunnel 2 to a depth required for a large underground architectural space; A PC material 5 is placed in the small-diameter shield tunnel 3 and
A step of introducing a necessary amount of prestress into the PC material 5 and then filling concrete to construct a horizontal PC beam frame 7 to complete an artificial roof, and the continuous underground wall 4 under the artificial roof. And constructing a large cavity 6 by excavating the internal ground 8 surrounded by the circles, and completing an architectural large space by constructing an internal building skeleton in the large cavity 6.

The shaft 1 serves as a starting base (and an end base) of a shield machine for excavating the large-diameter shield tunnel 2. It is also used for carrying out various materials, machinery and equipment for deep underground construction, and carrying out excavated soil.

Large-diameter shield tunnel 2 is small-diameter shield tunnel 3
It will be used as a starting point for shield machines for excavation, as a terminal station, and for ground surveys and groundwater pressure surveys. In addition to being a construction base for the continuous underground wall 4, it is also used for carrying in and out materials necessary for construction and carrying out excavated soil.

The small-diameter shield tunnel 3 is the base of an artificial roof (horizontal PC beam frame 7). This artificial roof exhibits great strength and rigidity by the effective action of the prestress introduced into the PC material 5, and as a large span horizontal PC beam frame 7 (horizontal water blocking wall) of 30m or more, the top of the large underground space To support the upper earth pressure and groundwater pressure applied to

The continuous underground wall 4 functions as a large-sized structure that supports lateral earth pressure and groundwater pressure applied to a large underground architectural space.

The large underground architectural space is a useful underground space for human life and various industries.

Embodiment Next, a first embodiment of the present invention shown in FIGS. 1 to 6 will be described.

FIG. 1 shows a stage in which a shaft 1 is excavated and constructed almost vertically to a predetermined artificial ground construction depth as a foothold for constructing an architectural large space under a large depth underground.

FIG. 2 shows that a large-diameter shield tunnel 2 is constructed horizontally from the lower end of the shaft 1, and then the base of the large-diameter shield tunnel 2 is used as a construction base, and an underground building is constructed vertically downward from this position. This shows a stage in which a continuous underground wall 4 is constructed by digging a trench to a depth necessary for the depth of the large space. Therefore, the large-diameter shield tunnel 2 is constructed by excavating four times along the top of the continuous underground wall 4 which is the outer peripheral wall frame of the underground architectural large space. The continuous underground wall 4 is used as an outer peripheral wall body (water stop wall) of the large underground architectural space. The continuous underground wall 4 may be constructed by an injection method. The shaft 1 and the large-diameter shield tunnel 2 are excavated and constructed with care not to impair the safety of existing buildings on the ground. The shaft 1 is used as a starting base for large-diameter shield machines, or used to carry in and out machines and equipment, and to carry out excavated soil. ing. To facilitate the construction of such a large-diameter shield tunnel 2, a shaft 1
Is preferably constructed by excavating at four corner positions of the continuous underground wall 4. In this way, the construction of the large-diameter shield tunnel 2
This is because two adjacent shafts 1,1 can be started and can be easily constructed between them as an end point base. In some cases, only one shaft 1 may be constructed, and the large-diameter shield tunnel 2 may be constructed in a horizontal annular shape. The large-diameter shield tunnel 2 is used for ground surveys and groundwater pressure surveys, as well as for carrying in and out of excavated soil for various types of building work described below. It is constructed in size (more than 5m in diameter). Further, in order to construct the floor area of the large underground space on a scale of about 2000 m ² or more, the length of one side or the plane diameter of the large diameter shield tunnel 2 is constructed on a scale of about 50 m or more. In the case of constructing the above-mentioned horizontal annular large-diameter shield tunnel, a shield machine of a so-called R-barrel whose steel shell is curved to the same curvature as that of the annular ring is used.

FIG. 3 shows a stage in which a large number of small-diameter shield tunnels 3... Are horizontally adjacently constructed in a horizontal plane surrounded by the large-diameter shield tunnels 2 constructed as described above. This small diameter shield tunnel 3 is 1m in diameter
It is about 2 m, and it is for constructing an underground artificial roof that keeps the safety and stability of existing buildings on the ground and the ground surface, so it is installed deeper than the support layer ground of the existing building Have been. Therefore, this small-diameter shield tunnel 3
It is also effective to construct an upwardly curved arch as shown by the dotted line in FIG. The small-diameter shield tunnel 3 is constructed in such a manner that the shield machine starts from the large-diameter shield tunnel 2 on one side and reaches the large-diameter shield tunnel 2 on the other side. This small-diameter shield tunnel 3 may be constructed as an independent tunnel adjacent to each other as shown in FIG. 5A, or a plurality of tunnels may be simultaneously connected by a multi-joint shield machine as shown in FIG. 5B. To shorten the construction period. The small-diameter shield tunnel 3 can be constructed not only with a circular cross section but also with a rectangular cross section. As a method of constructing the small-diameter shield tunnel 3, in addition to the above-described shield machine, it is also possible to apply a propulsion method or a flot jack method in which a front jack is used to pull. In addition, the small-diameter shield tunnel 3 constructed as an independent tunnel as shown in FIG. 5A excavates a small-diameter communication hole penetrating between adjacent ones, and a steel frame and a reinforcing bar are provided in each communication hole. By arranging and filling concrete or the like, mutual strong binding is performed to secure the rigidity required as an artificial roof.

Inside each small-diameter shield tunnel 3, there is a PC steel rod or PC
As shown in FIG. 5A or FIG. 5B, a PC material 5 such as a wire is arranged on the pulling side, and a prestress of a required size is introduced into the PC material 5 to prevent cracks in some cases. Reinforcement for shear reinforcement is placed, and concrete is filled into the entire cross section of the tunnel.
Is constructed.

FIG. 6 shows that an underground artificial roof (horizontal PC beam frame 7) is completed by combining all the small-diameter shield tunnels 3 arranged in parallel as described above into one plate. Then, a stage in which the large ground 6 is being constructed by excavating the inner ground 8 surrounded by the artificial roof and the continuous underground wall 4 is shown.
At the stage when the large cavity 6 is completed in this way, for example, athletic gyms or tennis courts, theaters, cinemas, gymnasiums, etc., so-called internal structures of the Ohbari area, are multi-layered like ordinary reinforced concrete or steel reinforced concrete buildings. It is built as a building structure on the floor. The completion of the internal building provides a large underground architectural space useful for the life, industry, and entertainment of people on the ground.

Second Embodiment FIGS. 7 to 10 show the underground floor of an existing building 11 on the ground and the underground floor structure portion 1 of each of two adjacent existing buildings 11, 11.
This section shows how to secure working spaces 13 and 14 in a part of 2 and build a large architectural space deep underground.

First, FIG. 7 shows a stage where a vertical shaft 13 and a large-diameter shield tunnel 14 in the horizontal direction are constructed in the basement structure portion 12 of the two existing buildings 11,11.

FIG. 8 shows a stage in which the continuous underground wall 4 is constructed vertically below using the horizontal large-diameter shield tunnel 14 as a construction base. The continuous underground wall 4 may be constructed by an injection method.

FIG. 9 shows the horizontal large-diameter shield tunnels 14 and 14 described above.
A large number of small-diameter shield tunnels are constructed in parallel between them, PC materials are placed in the small-diameter shield tunnels, concrete is introduced after the necessary prestress is introduced, and concrete is filled to construct a horizontal PC beam frame 7 This shows the stage when it was completed as an artificial roof.

This horizontal PC beam frame 7 is used for underground subway 15 and sewer pipe 16
It is built even deeper than facilities such as.

FIG. 10 shows a stage in which a large cavity 6 is being constructed by excavating the internal ground 8 surrounded by the artificial roof 7 and the continuous underground wall 4. The construction of an internal building in the large cavity 6 thus constructed and used as a large underground building space is the same as in the first embodiment.

Effects of the present invention As described in detail in conjunction with the embodiment above, according to the method of constructing a large deep underground building large space according to the present invention,
The presence of the ground of the existing building 11 does not become anything like failure, in deep underground beneath the supporting ground of the existing building 11, without exerting any adverse effects in the existing building 11 and the ground surface, the floor area of 2000m ² or more Architectural large space can be constructed. However, if there is enough space for construction (work) to excavate the shaft 1 or 13 on the ground, construction can be performed sufficiently, and it is possible to safely and accurately build the internal building frame of the large underground space at any depth. it can. Moreover, it can be easily implemented as an extension of the current construction technology.

Therefore, according to the present invention, it is possible to expect an effect of creating a large living space underground in an urban area where the population is concentrated and the land price is abnormally high, thereby braking the rise in land price.

[Brief description of the drawings]

FIGS. 1 to 6 and FIGS. 7 to 10 are cross-sectional views showing essential construction states of different embodiments of a method for constructing a large underground architectural large space according to the present invention. . 1: Vertical shaft, 2: Large-diameter shield tunnel 3: Small-diameter shield tunnel, 4: Continuous underground wall 5: PC material, 7: Horizontal beam frame 8: Ground, 6: Large cavity

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Tadahiro Kakizawa 2-5-14 Minamisuna, Koto-ku, Tokyo Inside Takenaka Corporation Technical Research Institute (72) Inventor Minoru Kawaharada 8-2-1-1, Ginza, Chuo-ku, Tokyo No. Takenaka Corporation Tokyo Main Branch (72) Inventor Yoshifumi Fujii 8-21-1, Ginza, Chuo-ku, Tokyo Co., Ltd. Takenaka Civil Engineering Co., Ltd. (56) References JP-A-3-84200 (JP, A)

Claims (1)

(57) [Claims] 1. A vertical pile reaching a deep underground, and a large-diameter shield tunnel is constructed from the vertical pile in a horizontal direction along a top of a planned outer peripheral wall of a large underground building space. Constructing a large number of substantially horizontal small-diameter shield tunnels in parallel in a plane surrounded by, and constructing a continuous underground wall directly below the large-diameter shield tunnel to a depth required for a large underground architectural space; Placing a PC material in the small-diameter shield tunnel, introducing a predetermined amount of prestress into the PC material, filling concrete, constructing a horizontal PC beam frame, and completing an artificial roof, Excavating the inner ground surrounded by the continuous underground wall under the roof to construct a large cavity, and constructing an internal building in the large cavity to complete an architectural large space; Underground with deep features How to build a huge space.