JPS6375290A - Method of underground junction construction of shield-tunnel and underground junction device - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

Detailed Description of the Invention "Field of Industrial Application" This invention is applicable to the ground excavation of a shield tunnel when excavating one tunnel from both ends using two shield machines and joining the tunnel in the middle. This article relates to the intermediate joint method and underground joint equipment.

"Prior Art" Conventionally, as a method for underground joining of this type of shield tunnel, the method shown in FIG. 7 is known.

In the figure, the symbol G is the ground near the junction of the shield tunnel that has been excavated from both ends, and within the ground G, the shield machine L that excavated one tunnel Ta is on the right side of the page, and the shield machine L that excavated one tunnel Ta is on the left side. The shield machine 2 which excavated the other tunnel Tb faces the shield machine 2 with a predetermined spacing (approximately 30 cm) left behind. The wall surface of the tunnel Ta5Tb formed behind the shield machine 1.2 is segment l□3a.

The lining is being carried out by 3b. In addition, at the tips of the shield machines 1 and 2, holes are drilled into the ground G at a predetermined angle of inclination (α=17° to 25°) with respect to the skin plates la and 2a, and at a predetermined pitch in the circumferential direction. type freezing tube 4a,
4b is installed, and skin brake 1-1a,
2a and the frontmost segments 3a and 3b, adhesive freezing tubes (not shown) are installed on the entire inner peripheral surface thereof. These perforated cryotubes 4a, 4b and stick-on cryotubes are connected to a freezing plant (not shown).

Then, the brine transferred from the freezing plant is circulated through the perforated freezing tubes 4a and 4b and the pasted freezing tubes installed on the skin plates la and 2a, thereby removing the ground mass Gi at the tunnel joint. After forming frozen soil Gf on the ground around the outer periphery of the skin plates 1a and 2a, the front parts 5a and 5b of the shield machine 1.2 are disassembled, and the remaining parts between the shield machines 1 and 2 are dismantled. The shield tunnel is completed by excavating the ground Gi and lining the walls thereof to connect the tunnels Ta and Tb that have been excavated from the left and right sides.

``Problems to be Solved by the Invention'' However, in the conventional shield tunnel joining method, a freezing method using the above-mentioned drilling type or pasting type freezing pipe is applied as an auxiliary method. In this case, a gap remains between shield machines 1 and 2, and in order to prevent water and earth from entering through this gap, a large frozen ground Gf is created near the joint between shield machines 1 and 2. This requires the formation of frozen soil, which requires a long period of time to form frozen soil, and a large amount of construction costs. There were various problems such as the expansion of frozen soil Gf and the risk of ground subsidence during thawing.

The present invention has been made in view of the above circumstances, and by reducing the size of the frozen soil Gf to be constructed on the ground G near the tunnel joint, the construction cost and construction period required for tunnel joint work can be reduced. The purpose is to provide an underground bonding method and underground bonding device for shield tunnels that can significantly reduce the cost.

"Means for Solving the Problems, 1" Therefore, in order to achieve the above-mentioned object, the first invention of the present invention is to excavate the ground using a cutter device provided at the curved part, and to provide a primary cover inside the ground. Using two shield machines that move underground while assembling construction segments, tunnels are excavated from both ends of the tunnel to be constructed, and the tunnels are joined in the middle to complete the tunnel. Under the underground bonding method, the tip of the skin plate of at least one shield machine is formed into a double layer with an outer cylinder and an inner cylinder, and a pasted freezing pipe is installed along the inner circumferential surface of this cylinder. In the process of excavating an tunnel using these two shield machines as a set, and during this tunnel excavation work, one of the shield machines
- A step in which the inner cylinder of the shield machine is advanced while excavating the ground at the joint of the flannel joint, and the inner cylinder closes the space between the skin plates of the two shield machines; Continuously, a step of freezing the ground around the tunnel joint with a stick-on freezing tube installed in the inner tube of one of the shield machines, and after the inner tube advancing step, freezing the ground of the two shields. The shield machine was dismantled with the skin plate of the machine remaining, and concrete was poured on the inner surface of the skin plate to line the wall surface of the joint.

Further, the second invention of the present invention is an underground shield tunnel having a structure in which a set of two shield machines is provided, tunnels are excavated from both ends of the tunnel to be constructed, and the tunnels are joined in the middle. In the joining device, the skin plate of at least one of the shielding machines is formed double by an outer cylinder and an inner cylinder, and the shielding machine is provided with a drive mechanism that slides the inner cylinder in the axial direction of the shielding machine, Furthermore, both of the shielding machines are provided with a moving mechanism for moving their respective cutter devices in the axial direction of the shielding machine, and a cooling tube is attached to the inner cylinder of one of the shielding machines along its inner circumferential surface. It is characterized by having the following.

``Function'' Since the inner cylinder of the skin plate remains as a lap joint connecting the ends of the opposing skin plate outer cylinders with a gap,
This inner cylinder acts as a support for the ground around the tunnel joint. Therefore, it is sufficient that the frozen soil formed in the ground around the tunnel joint by the attached freezing tube is small enough to be expected to have a water-stopping effect.

"Embodiment" Hereinafter, an embodiment of the present invention will be described with reference to FIGS. 1 to 6. In these figures, the same elements as those shown in FIG. 7 are given the same reference numerals.

In the figure, the symbol G is the ground near the junction of the shield tunnel excavated from both ends, and inside the ground G, the first shield machine l excavated the first tunnel Ta on the right side of the page. and the second shield machine 2 which excavated the other tunnel Tb on the left side at a predetermined interval (about 30 cm).
They face each other with the original ground Gi left behind. Further, the wall surface of the tunnel Ta formed behind the first shield machine 1 is lined with segments 3a, and the wall surface of the tunnel Ta formed behind the second shield machine 2 is lined with segments 3a.
The wall surface is lined with segments 3b. In the above configuration, the first shield machine 1
and the second shield machine 2 constitute an underground joining device S having a structure of excavating tunnels T a sTb from both ends of the tunnel to be constructed and joining them midway.

The first shield machine 1 includes a first outer skin plate (outer cylinder) la formed in a cylindrical shape, and an excavation equipment body housed inside the first outer skin plate (outer cylinder) la, which is slidable in the axial direction of the first shield machine 1. It consists of 11.

The excavation device main body 11 includes a first skin plate (inner cylinder) lla formed in a substantially cylindrical shape, and is provided inside the first skin plate (inner cylinder) lla,
A disk-shaped first partition plate 13 fixed at right angles to this skin plate lla, and a rear part of this partition plate 13 (tunnel T
The first support cylinder 12 has a diameter smaller than that of the first skin plate lla extending on the a side). In the front part of the first partition plate 13, a first cutter device 14 is provided with its shaft body 1.
5 is attached by being pivotally supported by the first partition plate 13. □Color. The first support tube 12 is slidably supported in the axial direction of the first shield machine 1 via a bearing portion 16 having a knoll mechanism, thereby supporting the excavation device main body 11 including the first cutter device 14. is supported slidably in the axial direction of the first shield machine l. Further, the first skin plate Ila is provided with a stick-on freezing tube 30 along its inner peripheral surface, and the stick-on freezing tube 30 can be connected to a freezing plant (not shown) as needed. be done.

The first shield machine l has a first skin plate auxiliary ring I in the middle of the inner peripheral surface of the first outer skin plate la.
A first propulsion jack 17 is fixed to the back surface (on the tunnel Ta side) at intervals in the circumferential direction. Similarly, a first auxiliary plate 18 is provided, and an extrusion jack (drive mechanism and moving mechanism) 19 is attached to this auxiliary plate 18 facing toward the first shielding machine 1. The active end 19a is in contact with the back surface of the first temporary partition 13.Furthermore, the first outer skin plate la and the first
A water stop means (not shown) such as a urethane glue seal is provided in the gap between the skin plate lla, and during excavation, grease etc. are supplied through a lubrication pipe (not shown). This prevents water from entering the gap. The first outer skin plate 1a and the excavator main body 11 are fixed by a fixing means (not shown) and are configured to move together during normal excavation.

On the other hand, the second shield machine 2 is provided with a second outer skin plate 2a formed in a cylindrical shape with the same diameter as the first outer skin plate 1a, and the tip of this outer skin plate 2a is , a second partition plate 23 is provided perpendicularly thereto.

In addition, a second cutter device 24 is provided at the front of the partition plate 23.
However, the shaft body 25 is attached by being pivotally supported by the second partition plate 23. Further, a second support cylinder 22 having a smaller diameter than the second outer skin plate 2a is provided behind the second temporary partition 23, and this support cylinder 22 is connected to the second support cylinder 22 through a bearing part 26 having a sealing mechanism. The second cutter device 24 is supported slidably in the axial direction of the shielding machine 2, so that the second cutter device 24 is slidably supported in the axial direction of the shielding machine 2.

Further, the second outer skin plate 2a has a second skin plate auxiliary ring 20 in the middle of the inner peripheral surface,
The back side of this skin plate auxiliary ring 20 (tunnel T
b side), a plurality of second propulsion jacks 27 are attached along the circumferential direction. Further, behind this skin plate auxiliary ring 20, a second auxiliary plate 28 is provided as in the first shield machine 1, and this auxiliary plate 28 is provided with a second shield machine 2. A retracting jack 29 (moving mechanism) is attached to the retracting jack 29, and the working end 29a of the retracting jack 29 is in contact with the back surface of the second partition plate 23. Further, the second outer skin plate 2a and the second cutter device 24 are configured to be fixed by a fixing means (not shown) and move together during normal excavation.

Next, the underground joining method of the present invention will be explained using FIGS. 2 to 6.

(i) First, cut one tunnel from the right side with respect to the page using the first shield tit and the first cutter device 1.
4, excavate the ground G, line the wall surface of the excavated shaft with segments 3a, take reaction force to the segments 3a and operate the first propulsion jack 17, thereby constructing one tunnel T a. At the same time, from the left side, the second shield machine 2 is used to excavate the ground G by the second cutter device 24, and the segment 3b is lined on the wall of the second shaft after excavation. By taking the reaction force and operating the second propulsion jack 27, the other tunnel Tb is constructed. Then, the first shield machine 1 and the second shield machine 2 are connected to the second shield machine 1 at the joining point.
As shown in the figure, a predetermined length of ground Gi (approximately 30 cm)
Leave them facing each other.

(11) Next, fixing means for fixing the first outer skin plate 1a of the first shield machine 1 and the old theater device main body ll, and the second outer skin plate 2a of the second shield machine 2 and the second
The fixing means with the cutter device 24 is released.

(iii) Next, as shown in FIG. 3, the second cutter device 24 is moved to the second outer side by driving the retracting jack 29 while leaving the first and second outer skin plates La and 2a as they are. While sliding on the skin plate 2a, the second skin plate 1 and the auxiliary ring 2
At the same time, the first cutter device 14 and extrusion jack 19 are driven to excavate the ground G1 left between the two shield machines 1 and 2, and the excavator body 11, its first skin plate Ila
is advanced while sliding against the first outer skin plate 1a.

(iv) First skin plate 1 of H excavation equipment main body 11
1a slides and reaches a position where it just straddles and closes the gap between the first and second outer skin plates la and 2a, as shown in FIG. stop. At the same time, an adhesive freezing tube 3 provided on the inner circumferential surface of the first skin plate lla
Brine transferred from a freezing plant (not shown) is circulated within the tunnel joint, thereby cooling the ground Gi
first and second outer skin plates la, surrounding the
Frozen soil Gf is formed on the ground around the outer periphery of 2a.

(v) Next, as shown in FIG.
And the 11th second propulsion jack 17.27 will also be dismantled.

As a result, tunnel Ta and tunnel Tb penetrate to form one tunnel.

(vi) After that, both ends of the first skin plate lla remaining in a state of covering the gap formed between the first and second outer skin plates la and 2a from the inside thereof,
The first outer skin plates 1a and 2a are welded and fixed from the inside, respectively. Thereby, this first skin plate lla acts as a sleeve-shaped lap joint.

(vii) Finally, construction of the joint is completed by pouring concrete 31 on the inner wall surface of the skin plate.

"Effects of the Invention" As explained above, according to the present invention, after dismantling the excavator main body, the inner cylinder of the skin plate is formed into a sleeve-like stack that connects the ends of the opposing skin plate outer cylinders with a certain gap. By leaving the joints on the inner peripheral surface of the skin plate outer cylinder, it is possible to provide support for the ground around the tunnel joint, and therefore, the frozen soil can be protected by the pasted freezing pipe installed in the skin plate inner cylinder. Since the scale of formation can be made small enough to be expected to have a water-stopping effect, it is possible to significantly reduce the construction cost and construction period required for tunnel joining work. Further, according to the present invention, by reducing the scale of frozen soil formation, the perforated freezing pipes required in the conventional freezing method are no longer necessary, and the construction period and cost required for installation thereof are eliminated. It is possible to save labor in temperature measurement and management, and it has excellent effects such as eliminating the fear of expansion of frozen soil during freezing and subsidence of ground during thawing.

[Brief explanation of the drawing]

FIG. 1 is a side sectional view showing an underground joint device for a shield tunnel which is an embodiment of the second invention of the present invention, and FIGS. 2 to 6 are respectively the embodiments of the first invention of the present invention. FIG. 7 is a side sectional view illustrating a method for underground joining of a shield tunnel, which is an embodiment, and FIG. 7 is a sectional side view illustrating a conventional underground joining method for a shield tunnel. S: underground bonding device, ■: first shield machine, 1a: first outer skin plate (outer cylinder), 2: first 2 shield machine, 2a...second outer skin plate, 11...excavation equipment main body, lla...
1st skin plate (inner cylinder), 21a...2nd
skin plate, 14.24... cutter device,
17.27...propulsion jack, 19...
・Extrusion jack (drive mechanism, movement mechanism), 29...
...Retraction jack (moving mechanism), 30...
Stick-on freezing tube.

Claims (2)

[Claims] (1) Using two shield machines that propel the tunnel underground while excavating the ground using a cutter device installed at the front and assembling segments for the primary lining inside, the tunnel is constructed from both ends of the tunnel. An underground joining method for shield tunnels, in which the tunnels are completed by excavating tunnels and joining them midway, wherein the tip of the skin plate of at least one of the shield machines is connected to the outer cylinder and the inner cylinder. A process of forming a double layer by forming a double layer and installing a pasted freezing pipe along the inner peripheral surface of this inner cylinder, and excavating a tunnel using these two shield machines as a set, and immediately before the end of this tunnel excavation process. , while excavating the ground at the tunnel joint with one shield machine, advancing the inner cylinder of this shield machine, and closing between the skin plates of each of the two shield machines with this inner cylinder, and the step Concurrently with this step, a step of freezing the ground around the tunnel joint with a stick-on freezing tube installed in the inner cylinder of one of the shield machines, and after the end of the inner cylinder advancing step, the step of
A shield tunnel comprising the steps of dismantling the shield machine with the skin plate of the shield machine remaining, and further lining the wall surface of the joint by pouring concrete on the inner surface of the skin plate. Underground joint method. (2) A pair of shield machines are equipped to excavate the ground using a cutter device installed at the front, while assembling segments for the primary lining inside to propel the tunnel. An underground joint device having a structure in which tunnels are excavated from both ends and joined in the middle, wherein the skin plate of at least one of the shield machines is formed double by an outer cylinder and an inner cylinder, and , this shielding machine is provided with a drive mechanism that slides the inner cylinder in the axial direction of the shielding machine, and both of the shielding machines are further provided with a movement mechanism that moves the respective cutter devices in the axial direction of the shielding machine. An underground joining device for a shield tunnel, characterized in that the inner cylinder of one of the shield machines is provided with a pasted cooling pipe along the inner peripheral surface thereof.