JPH0684712B2 - High water pressure pipe roof construction method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (a). BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pipe roof construction method under high water pressure such as deep underground.

(B). 2. Description of the Related Art Conventionally, pipe roof construction has been performed by driving a pipe into a natural ground from an excavated site such as a vertical shaft.

(C). Problems to be Solved by the Invention However, under high water pressure such as deep underground, when driving a pipe, groundwater is blown out from the inside of the pipe or the like, which makes construction difficult.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a high water pressure pipe roof construction method capable of suitably performing construction under high water pressure in order to solve the above problems.

(D). Means for Solving the Problems That is, the present invention, in the construction of the pipe roof (11),
When installing the pipe (12) in the natural ground (3), the mud-type propulsion excavator (13) is used to excavate the natural ground (3) to form the pipe burying hole (3b). Insert the pipe (12) to be installed into the pipe burying hole (3b),
When the formation of the hole (3b) for burying the pipe and the insertion of the pipe (12) into the hole (3b) for burying the pipe are completed, the face (3a) and the muddy water type excavator (13) are separated. While filling the filler (25), the muddy water type propulsion excavator (13) is retracted to fill the inside of the pipe (12) with the filler (25), and the ground (3) is piped (12). ) Is installed in a pipe (12) filled with a filler (25).

The numbers in parentheses are for convenience of showing the corresponding elements in the drawings, and therefore the present description is not limited to the description in the drawings. The same applies to the section "(e). Action" below.

(E). Operation With the above-described configuration, the mud-type propulsion excavator (13) functions to install the pipe (12) while excavating the natural ground (3).

(F). Embodiments Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a front sectional view showing an example of a tunnel widening construction site to which the pipe roof construction method for high water pressure according to the present invention is applied, FIG. 2 is a sectional view taken along line II-II of FIG. 1, and FIG. Is a front sectional view showing a state of pipe roof construction, FIG. 4 is a sectional view taken along line IV-IV of FIG. 3, and FIG. 5 shows an embodiment of the pipe roof construction method for high water pressure according to the present invention. Front sectional view, FIG. 6 is a front sectional view showing a state of freezing, FIG. 7 is a sectional view taken along line VII-VII of FIG. 8, FIG. 8 is an enlarged view of FIG. 7, and FIG. Is a front sectional view showing a state of the widening work, and FIG. 10 is a sectional view taken along line XX of FIG.

At the tunnel widening construction site 1, as shown in FIG. 1, a vertical shaft 5 is formed vertically downward from the ground 2, that is, in the downward direction in the drawing. Inside the vertical shaft 5, an earth retaining wall 6 is formed. It is provided to counter the earth pressure and water pressure of the mountain 3. And, in the lower part of the shaft 5 in the figure, as shown in FIG. 1 and FIG.
A tunnel 7 such as a subway is formed by a shield excavator or the like in a horizontal direction, that is, a horizontal direction in the figure, in a manner that the inside of the tunnel 7 and the inside of the shaft 5 communicate with each other. Then, inside the tunnel 7, a segment 9 is assembled and installed in a cylindrical shape having a predetermined inner diameter D1 so as to oppose the earth pressure and water pressure of the natural ground 3, and is described below in the vicinity of the vertical shaft 5. On the outer peripheral surface of the steel segment 9 installed at the position corresponding to the widening section 10, as shown in FIG. 1 and FIG.
9a is installed.

And, as the installation section etc. near the subway station part,
As shown by the chain double-dashed line in the figure, when forming the widened section 10 having the inner diameter D2 larger than the inner diameter D1 of the tunnel 7, the tunnel 7 is expanded from the vertical shaft 5 as follows. To do.

First, as shown in FIG. 3 and FIG. 4, a plurality of steel pipes 12 for pipe roof are arranged in an annular shape around the tunnel 7 so as to be in contact with each other, and the vertical shaft 5 is parallel to the axial direction of the tunnel 7. Is buried in the direction of arrow A from a predetermined section length L, and a pipe roof 11 having an inner diameter D3 which is larger than the inner diameter D2 to be enlarged by the thickness of a steel support 29 described later is formed into a cylindrical shape so as to surround the tunnel 7. To form.

Mud-type propulsion excavator used for construction of pipe roof 11
As shown in FIG. 5, has a cylindrical main body 15 having an outer diameter smaller than the inner diameter of the pipe roof steel pipe 12 to be buried, and the main body 15 has a partition wall 15a and a space inside the main body 15. Is cut off in the directions of arrows A and B. A circular cutter 16 corresponding to the outer diameter of the pipe roof steel pipe 12 to be buried is provided on the front surface of the main body 15, that is, on the side of the partition wall 15a in the direction of arrow A so as to be rotatable and driven by a drive motor (not shown). There is. In addition, the chamber 1 between the cutter 16 and the partition wall 15a
The muddy water pipe 17 is connected to 5c, and a flange 15b is provided at the rear end of the main body 15, that is, the end on the arrow B direction side.

The muddy water propulsion excavator 13 is arranged inside the pipe roof steel pipe 12 in which the main body 15 is to be buried, and the cutter 16
Is arranged in front of the steel pipe 12 for pipe roof, that is, in the direction of arrow A, and a packer 19 is mounted in a gap between the main body 15 and the steel pipe 12 for pipe roof so as to seal the gap. Further, a plurality of pipe roof steel pipes 12 are assembled in an annular shape with a length RL and are connected in a plurality of directions in the directions of arrows A and B. Further, a main body 15 is also provided with a length RL and is used as a pipe roof steel pipe. 12
A plurality of propulsion steel pipes 20 assembled in an annular shape having an outer diameter smaller than the inner diameter of the bolts are bolted through the flanges 15b and 20a, and the arrow A is parallel to the pipe roof steel pipe 12.
It is connected in the B direction, and the rear of the connected steel pipe 12 for pipe roof and the steel pipe 20 for propulsion, that is, the arrow B direction side is a shaft 5
It extends into the interior. And the last one, that is, the most arrow B
_A push ring 21 formed in an annular shape is connected to the rear ends of the pipe roof steel pipe 12 _A and the propulsion steel pipe 20 _A , which are connected to the direction side, that is, the ends on the arrow B direction side. On the arrow B direction side of the wheel 21, a plurality of rams 22a of the propulsion jacks 22 are provided.
However, it is mounted so as to project and retract in the directions of arrows A and B. An entrance steel pipe 23 is installed on the earth retaining wall 6 inside the vertical shaft 5 so as to surround the steel pipe 12 for pipe roof, and the entrance steel pipe 23 has an entrance packing.
23a is mounted so as to seal the gap between the entrance steel pipe 23 and the pipe roof steel pipe 12.

Since the mud-type propulsion excavator 13 and the installation form of the mud-type propulsion excavator 13 have the above-described configuration, when the pipe roof steel pipe 12 is buried in the natural ground 3, the mud-type propulsion excavator 13 is used.
The cutter 16 is driven to rotate, and the ram 22a of the propulsion jack 22 is projected together with the push wheel 21 in the direction of the arrow A to advance the main body 15 through the propulsion steel pipe 20, while the cutter 16 is moved through the main body 15. It is pressed in the direction of the face 3a, that is, in the direction of arrow A.
Then, due to the pressing force, the cutter 16 and the cutting face 3a come into contact with each other at a predetermined contact pressure, the cutting face 3a is excavated by the cutter 16, and the excavated earth and sand is discharged to the outside through the sending and discharging mud water pipe 17,
A hole 3b is formed behind the cutter 16. At the same time, the steel pipe 12 for pipe roof is integrally advanced with the muddy water type propulsion excavator 13 in the direction of arrow A via the propulsion jack 22 and the push wheel 21, and the steel pipe 12 for pipe roof is excavated and formed by the cutter 16. Insert into 3b. Then, the mud-type propulsion excavator 13 digs in the direction of arrow A by the length RL of one ring of the pipe roof steel pipe 12 and the propulsion steel pipe 20, and the pipe roof steel pipe 12 is moved by the mud-type propulsion excavator 13. When it is inserted into the formed hole 3b in the direction of arrow A, the ram 22a of the propulsion jack 22 and the push ring 21 are selectively retracted in the direction of arrow B so as to counteract the earth pressure and water pressure of the natural ground 3. Then, the rearmost, i.e. the most since the space between the arrow B direction side of the pipe roof steel pipe 12 _A and propulsion steel pipe 20 _A and press wheel 21 is formed, a new pipe roof length RL in the space sequentially inserting assemble use steel pipe 12 and the propulsion steel 20, the rear end portion of the steel pipe for the pipe roof, respectively 12 _a and propulsion steel pipe 20 _a, that is connected to the end of the arrow B direction side. When a new steel pipe 12 for pipe roof and a new steel pipe 20 for propulsion are added, the cutter 16 of the muddy water type propulsion excavator 13 is driven to rotate again, and the ram 22a and the push ring 21 of the propulsion jack 22 are projected in the arrow A direction. Then, excavation by the mud-type propulsion excavator 13 and embedding of the steel pipe 12 for pipe roof are performed for each length RL from the vertical shaft 5 to the section length L shown in FIG. At this time, the mud-type propulsion excavator 13
The pipe roof steel pipe 12 and the pipe roof steel pipe 12 are integrally advanced in the direction of arrow A through the same propulsion jack 22, and the space between the mud-type propulsion excavator 13 and the pipe roof steel pipe 12 is stopped by the packer 19. Since water is stopped by the entrance packing 23a between the pipe roof steel pipe 12 and the entrance steel pipe 23, the pipe roof steel pipe 12 can be suitably embedded even under high water pressure such as deep underground.

Then, when the steel pipe 12 for pipe roof is buried up to the vertical shaft 5 or the section length L as shown in FIG. 3, it is used for discharging excavated sediment during excavation. A filler 25 such as an air mortar having good fluidity is supplied to the inside of the steel pipe 12 for pipe roof through the pipe, and the filler 25 is filled between the cutter 16 and the face 3a while the mud-type propulsion excavator 13 is moved in the direction of arrow B. Back to the mud-type propulsion excavator 13 steel pipe for pipe roof 12
Take out from inside. Then, the interior of the pipe roof steel pipe 12 that has been buried is filled with the filler 25, and the water is stopped by the filler 25, so that the pipe roof 11 can be preferably constructed even under high water pressure such as deep underground. You can go.

In this way, the steel pipe 12 for pipe roof is tunneled from the vertical shaft 5 through the muddy water propulsion excavator 13 at each position around the tunnel 7 arranged in an annular shape as shown in FIG. 4 as described above. A ground pipe 3 is embedded in parallel with 7 (perpendicular to the plane of FIG. 4), and the inside is filled with a filler 25 to be embedded, and a pipe roof 11 is formed in a cylindrical shape so as to surround the tunnel 7.

When the pipe roof 11 is formed, as shown in FIG.
The hardened filler 25 inside each pipe roof steel pipe 12 is located at a position SP closest to the segment 9 (a position inside the pipe roof 11) and a position closest to the adjacent pipe roof steel pipe 12 (each pipe roof steel pipe). Joint part where 12 contacts 11
At position b) PP, as shown in FIG. 6, boring from the vertical shaft 5 side in parallel with the steel pipe 12 for pipe roof,
The freezing tubes 26 are installed at the drilled positions SP and PP.
Therefore, two freezing pipes 26 are installed inside each pipe roof steel pipe 12. Further, as shown in FIGS. 6 and 7, the freezing pipe 27 is formed so as to radially project from the inside of the tunnel 7 to the outside of the segment 9, in the vicinity of the tip portion 12a of the steel pipe 12 for pipe roof, that is, the widening section 10 Install near the end of. Then, the ground 3 between the pipe roof 11 and the segment 9 of the tunnel 7 is frozen by the pasting freeze pipe 9a installed on the outer peripheral surface of the segment 9 and the freeze pipes 26 and 27 described above,
Frozen soil 3c is formed. The pipe roof steel pipe 12 is not provided with a junction for connecting the pipe roof steel pipes 12 to each other in the joint portion 11b in order to simplify the above-described excavation mechanism, but the joint portion 11b is installed near the position PP. The freezing pipe 26 freezes the natural ground 3 to stop the water.

Thus, when the frozen soil 3c is formed to stop the water, the segment 9 on the vertical shaft 5 side of the tunnel 7 is disassembled and removed, and the segment 9 is exposed in the tunnel 7 as shown in FIG. Excavate the frozen soil 3c inside the pipe roof 11. Then, inside the pipe roof 11 exposed in the tunnel 7 due to the excavation of the frozen soil 3c, steel support 29
Is installed in an annular shape having an inner diameter D2 to support the pipe roof 11. In this way, by sequentially removing the segment 9 from the vertical shaft 5 side, excavating the frozen soil 3c, and installing the steel support 29, the inner diameter D1 of the tunnel 7 is enlarged to a predetermined inner diameter.
A widening section 10 of D2 is formed.

Therefore, the widening section 10 can be formed by enlarging the inner diameter of the tunnel 7 from the vertical shaft 5 side constructed by the minimum excavation without excavating the entire widening section 10. Even in the development of, it is possible to construct the widening section 10 in a relatively short period of time relatively easily.

(G). As described above, according to the present invention, when the pipe such as the steel pipe 12 for pipe roof is installed in the ground 3 in the construction of the pipe roof 11, the mud-type propulsion excavator 13 is used. Excavating, to form a pipe burying hole such as the hole 3b, insert the pipe to be installed in the pipe burying hole, form the pipe burying hole and the pipe burying hole. When the insertion of the pipe is completed, while filling the filling material 25 between the face 3a and the muddy water type propulsion excavator 13, the muddy water type propulsion excavator 13 is retracted, and the filling material 25 is placed inside the pipe. Since it was configured to be installed by installing the pipe in the ground 3 and filling the inside of the pipe with the filler 25, the pipe was installed while excavating the ground by the muddy water type excavator 13. After completion of burying the pipe in the ground 3, While retracting the excavator 13 by filling the filler 25 in the interior of the pipe, while effectively water-shutoff even under high pressure, it is possible to lay the pipe roof 11.

[Brief description of drawings]

FIG. 1 is a front sectional view showing an example of a tunnel widening construction site to which the pipe roof construction method for high water pressure according to the present invention is applied, FIG. 2 is a sectional view taken along line II-II of FIG. 1, and FIG. Is a front sectional view showing a state of pipe roof construction, FIG. 4 is a sectional view taken along line IV-IV of FIG. 3, and FIG. 5 shows an embodiment of the pipe roof construction method for high water pressure according to the present invention. Front sectional view, FIG. 6 is a front sectional view showing a state of freezing, FIG. 7 is a sectional view taken along line VII-VII of FIG. 6, FIG. 8 is an enlarged view of FIG. FIG. 10 is a front sectional view showing a state of widening work, and FIG. 10 is a sectional view taken along line XX of FIG. 3 …… Solid ground 3a …… Face face 3b …… Pipe burying hole (hole) 11 …… Pipe roof 12 …… Pipe (steel pipe for pipe roof) 13 …… Muddy water propulsion excavator 25 …… Filling material

Claims (1)

[Claims] 1. When constructing a pipe on a rock in pipe roof construction, a mud-type propulsion excavator is used to excavate the rock to form a hole for burying the pipe, and the hole for burying the pipe. After inserting the pipe to be installed, forming the pipe burying hole and inserting the pipe into the pipe burying hole, a filler is filled between the face and the muddy water type propulsion excavator. Meanwhile, the mud-type propulsion excavator was retracted, the inside of the pipe was filled with the filler, and the pipe was installed in the ground with the filler filled inside the pipe. High water pressure pipe roof construction method.