JPH0235190A - Multicore-parallel optional section shield machine - Google Patents

Abstract

PURPOSE:To form a drilling section into an optional form in an efficient manner by setting up a sub-shield machine or a jet nozzle in a recess produced in both upper and lower parts between faceplates of plural units of paralleled main shield machines. CONSTITUTION:Plural units of main shield machine 6, 7 are combined into a solid type in response to a desired drilling section and installed in parallel, thereby constituting a multicore-parallel optional section shield machine 1. Next, each of required numbered sub-shield machines 3 or jet nozzles are set up in a recess in both upper and lower parts between faceplates of the main shield machines 6, 7. In this connection, an over cutter may be set up in a rear part of these faceplates of the main shield machines 6, 7 so as to make it retractable, instead of this constitution. With this constitution, digged earth is sharply reduced and, what is more, labor and expense can be curtailed.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] This invention relates to a multi-core parallel shielding machine of arbitrary cross section.

[Conventional technology]

Conventionally, when building subways in urban areas, it has been common to excavate large spaces below the ground surface, such as stations, using the so-called open cut construction method.

However, according to the open cut construction method, excavation has had a wide range of adverse effects on above-ground structures, such as poor ground quality.

Also, due to the construction method, it is necessary to excavate over a wide area,
This meant excavating more underground space than was purely necessary, increasing construction costs considerably, and also requiring a considerable amount of excavated soil, which also became a problem that needed to be resolved.

Therefore, Ganto Toyama previously developed a multi-core parallel integrated shield machine that includes multiple shield machines, and filed two or three applications for the same.

[Problem to be solved by the invention]

However, the conventional multicore parallel integrated shield machine has a problem in that the portions corresponding to the upper and lower recesses between the face plates of each shield machine cannot be excavated structurally.

Therefore, the shape of the tunnel excavation cross section was naturally limited.

This invention was proposed in view of the above-mentioned conventional circumstances, and is an improvement and development of the multi-core parallel integrated shield machine. It is an object of the present invention to provide a multi-core parallel shielding machine capable of excavating a tunnel with an arbitrary cross section by making it possible to excavate a portion corresponding to a recess.

[Means to solve problems]

The present invention relates to a two or three core parallel arbitrary cross-section shielding machine which is equipped with a plurality of shielding machines, or a reciprocal parallel arbitrary cross-section shielding machine, in which a plurality of main shielding machines are installed together as an integrated type, and the main shielding machines are installed together. Install multiple sub-shield machines or jet nozzles in the upper and lower recesses between the face plates of the shield machine, or install a plurality of sub-shield machines or jet nozzles over the edge of the face plate of the shield machine instead of installing a sub-shield machine, etc. It is characterized in that the cutter is installed so that it can protrude or recess from the edge of the face plate.

[Embodiment] Hereinafter, a description will be given based on an embodiment illustrating a multi-core parallel arbitrary cross section shielding machine according to the present invention.

The multicore parallel integrated shield machine 1 shown in Figs. 1, 2, and 3 has two main shield machines 2.2 installed side by side with their face plates 2a and 2a overlapping on the same plane. At the same time, a plurality of sub shield machines 3. ... (see Fig. 1) or a plurality of jet nozzles 4 (see Fig. 2).

Main shield machine 2 and secondary shield machine 3. ... are constructed so that both can be excavated simultaneously and integrally using a rotary cutting method.

Further, the jet nozzle 4 can excavate rock by jetting water at high pressure.

Furthermore, the slave shield machine 3. The excavation cross section of the upper and lower recesses S between the face plates 2'a and 2a can be freely changed by appropriately increasing or decreasing the number of nozzles 4, . Yes (see Figure 3).

The multi-core parallel arbitrary cross section shielding machine 1 shown in FIG. 4 includes a secondary shielding machine 3. . . . etc., over cutters 5, 5 are installed instead.

The over cutter 5 is the face plate 2a of the main shield machine 2.2,
2a, and the surface Fi2a.

It is configured so that it can protrude or recess by a predetermined length from the edge of 2a.

Then, by this over cutter 5, the face plates 2a, 2
The structure is such that it is possible to excavate the upper and lower recesses S between a.

In the multicore parallel arbitrary cross section shielding machine 1, the excavation cross section of the upper and lower recesses S between the face plates 2a, 2a can be arbitrarily changed by appropriately changing the protruding length of the over cutters 5, 5. It is.

The shield tunnels having the cross sections shown in FIGS. 1 to 4 are applied to double-track railway tunnels, but they can also be applied to road tunnels, waterway tunnels, etc.

Figures 5, 6 and 7 show three-core parallel multi-core arbitrary cross-section shielding machines, among which the multi-core parallel arbitrary cross-section shielding machine 1 shown in Figs. Both end main shield machines 7.7 are installed at both ends of the main shield machine 6, and the face plates 6a of the central main shield machine 6 and both end shield machines 7.7 are installed.
It is constructed by installing a shield device 3 (see Fig. 5) and a shed nozzle 4 (see Fig. 6) according to the upper and lower recesses S between and 7a.

In addition, the central main shield machine 62, the main shield machine 7.7 at both ends, and the secondary shield machine 3. ...all use rotary cutting type shield machines.

The multi-core parallel arbitrary cross-section shielding machine shown in FIG.
Shield machine 3 according to the upper and lower recesses S between the face plates 6a and 7a.
．． ... etc. instead of installing over cutter 5.5
This is what was installed.

The over cutter 5 is installed at the edges of the face plates 6a and 7a of the central main shield machine 6 and the both end main shield machines 7, and is configured to protrude or recess to a predetermined length from the edge parts of the face plates 6a and 7a. It has become.

The structure is such that the overcutter 5 can excavate the rock between the face plates.

Further, a rotary excavation type shield machine is used as the central main shield machine 6, and an oscillating excavation type shield machine is used as the both end main shield machines 7.

In addition, the central main shield machine 6 and the main shield machines 7 and 7 of the multi-core parallel arbitrary cross section shield machines shown in FIGS. 5, 6, and 7 can excavate as a unit, and It is also configured so that only the center main shield machine 6 or only the both end main shield machines 7 and 7 can excavate independently.

Furthermore, the slave shield machine 3. By appropriately increasing or decreasing the size, the number of installed jet nozzles 4, and the number of installed jet nozzles 4, the excavation cross section between the face plates can be excavated into an arbitrary shape.

The multi-core parallel integrated shield machine 1 shown in FIGS. 8 and 9 is a three-core multi-core parallel parallel silt machine with arbitrary cross sections. 7
This differs from the multi-core parallel arbitrary cross section shielding machine 1 of FIG. 5 in that the face plates 6a and 7a are slightly shifted back and forth, but the other points are substantially the same.

In these figures, when separating the both-end shield machine and leaving only the central main shield machine 2, in the case of Fig. 8, part of the face plate 7a is removed from the inside of the shield machine, and the face plate 7a is removed from the inside of the shield machine.
Separate and dig.

Moreover, in the case of FIG. 9, the face plate 7a is removed from the shield machine, and the shield machine 6 is made into an independent shield machine.

Figures 10, 11, and 12 show the multi-core parallel arbitrary cross-section shield machine of the remembrance, among which the multi-core parallel arbitrary cross-section shield machine 1 shown in Fig. 10 is the central main shield machine 6.
Both end main shield devices 7, 7 are installed at both ends of the main shield device 3.6, and a secondary shield device 3. It is constructed by installing...

Central main shield 16. Both ends main shield machine 7゜7 and secondary shield machine 3. ...all use rotary cutting type shield machines.

Moreover, the multi-core parallel arbitrary cross-section shield machine shown in FIGS. 11 and 12 differs from the multi-core parallel integrated shield machine shown in FIG. 10 in that the face plates 6a and 7a are shifted back and forth, and other points are omitted. It is the same.

When making a standalone shield machine, remove part of the face plate and separate the left and right sides.

Figures 13 to 16 and Figures 17 to 19 are Figure 5;
This figure shows a subway station and a tunnel excavated by the multicore parallel arbitrary cross section shielding machine 1 shown in FIGS. 6, 7, and 9.

Moreover, FIGS. 21 to 24 show station areas and tunnels excavated by the multi-core parallel arbitrary cross-section shield machine shown in FIGS. 10, 11, and 12.

In either case, the inner periphery of the station and tunnel will be lined with segments or cast-in-place concrete.

In these figures, number 8 is a pillar and number 9 is a platform.

These pillars may be erected at the same time as the segments during lining construction, but when using one segment assembly machine in the center of the tunnel, after the surrounding segments have been assembled, the segment assembly material advances one ring, and then it is assembled between the segments. You can.

Next, a shielding method using a multi-core parallel arbitrary cross-section shielding machine according to the present invention will be explained (see FIGS. 13 to 16).

(1) First, the shaft A is excavated to a predetermined depth using the conventional open cut method or the like.

(2) Next, a multi-core parallel arbitrary cross section silt machine 1 is installed in the shaft A.
The central main shield machine 62, the main silt machines 7 and 7 at both ends, and the secondary shield machine 3. ... is set up in a three-way dotted state.

(3) Next, the central main shield machine 62 and the main silt machines 7 at both ends.
．． 7 and secondary shield machine 3. A tunnel B is excavated by a multi-core parallel integrated shield machine 1 consisting of... After tunnel B is excavated, a station platform 9 will be constructed in shaft A and tunnel B, and rails will be laid.

(4) Next, the central main shield machine 6 is connected to the slave shield machines 7, 7 at both ends, and the slave shield machine 3. ...and then separate and excavate tunnel C using the central main shield machine 6 alone. After tunnel C is excavated, rails are laid in tunnel C.

Here, an example is shown in which a vertical shaft is installed on the platform (first
(See Figure 3), generally a vertical shaft is provided at the boundary between Tunnel C and Tunnel B (see Figure 17), and the station section and the attachment points before and after it are excavated as Tunnel B.

A water stop wall with a rectangular cross section is installed in the center and front and rear ends of the station platform before tunnel excavation, and after the tunnel is excavated, it is excavated from above and a vertical shaft is installed there using the reverse winding method to connect with the tunnel, such as stairs, escalators, etc. Place.

Figures 17 to 20 show the case where a three-core shield machine is used to excavate an oval shape with a cross section close to a circle, and in this case, the pillars can be omitted.

Figures 21 to 24 show the case in which excavation was performed using a similar shield machine to have an oval shape with a cross section close to a circle, and in this case, a pillar was provided in the center. After excavating the station area, it turns into a multi-center eyeglass-shaped shield machine and excavates.

[Effects of the Invention] Since the present invention has the above configuration, it has the following effects.

(1) The rock between the face plates of multiple shield machines installed in parallel can be excavated by multiple slave shield machines, jet nozzles, or overcutters, and the number and size of the slave shield machines installed By appropriately increasing or decreasing the number of jet nozzles installed, the excavation cross section between the face plates can be made into any shape, so the excavation cross section of the entire tunnel can be freely changed as necessary.

(2) When excavating a large underground space such as a station area, there is no need to excavate the entire station area using the so-called open cut method, etc., and it is only necessary to excavate the vertical shaft necessary for installing the shield machine.

Therefore, since the excavation range can be made as small as possible, there is no need to worry about adverse effects such as poor ground quality on above-ground structures.

(3) Furthermore, since the amount of soil excavated and discharged is greatly reduced, the labor and cost required for its disposal can be saved, and construction costs can be significantly reduced.

[Brief explanation of the drawing]

Figures 1 to 12 show a multi-core parallel arbitrary cross-section shield machine according to the present invention, and Figures 1, 2, 3, and 4 show two-core parallel multi-core arbitrary cross-section shields. front view of the machine,
Figures 5, 6, 7, 8, and 9 show three-core multi-core shielding machines with arbitrary cross sections.
Figures 7 and 7 are front views, Figures 8 and 9 are plan views, Figures 10 and 11 are front views of the multi-core parallel arbitrary cross section shield machine, and Figure 12 is its top view. , Fig. 13 to Fig. 16 show a subway station section excavated by a multi-core parallel arbitrary cross section shield machine, Fig. 13 is a plan view thereof, and Fig. 14 is a cross-sectional view taken along the line E in Fig. 13. , Fig. 15 is a sectional view of the Roro line in Fig. 13, Fig. 16 is a sectional view of the Harbor line in Fig. 13, Figs. Its plan view, FIG. 18 is a sectional view taken along the line 2-2 in FIG. 17,
Figure 19 is a sectional view along the Hohe line in Figure 17, Figure 20 is a sectional view along the Hohe line in Figure 17, and Figures 21 to 24 also show the subway station area. Its plan view, FIG. 22 is a sectional view taken along the Thoth line in FIG. 21,
23 is a sectional view along the Cheech line in FIG. 21, and FIG. 24 is a sectional view along the Lie line in FIG. 21. 1...Multi-core parallel arbitrary cross section shield machine, 2...Main silt machine 2.3...Sub shield machine, 4...Jet nozzle, 5...Over cutter 6...Central main silt machine , 7... Main shield machine at both ends, 8... Pillar, 9...
platform. ] ○

Claims (1)

[Claims] 1. In a multi-core parallel arbitrary cross-section shielding machine configured by installing a plurality of shielding machines, two main shielding machines are installed together, and the face plate of the main shielding machine A multi-core parallel arbitrary cross-section shield machine characterized by having a plurality of sub-shield machines installed in the recess between the face plate and the face plate. 2. In a multi-core parallel arbitrary cross section shielding machine configured by installing a plurality of shielding machines side by side, two main shielding machines are installed side by side and a recess between the face plates of the main shielding machines. A multi-core parallel arbitrary cross-section shield machine characterized by having multiple jet nozzles installed in the machine. 3. In a multi-core parallel arbitrary cross-section shielding machine configured by installing multiple shielding machines side by side, two both-end main shielding machines are installed at both ends of one central main shielding machine so that they can be separated. At the same time, a plurality of sub-shielding machines are installed in recesses between the face plates of the central main shielding machine and the both-end main shielding machines. 4. In a multi-core parallel arbitrary cross section shielding machine configured by installing multiple shielding machines side by side, two both-end main shielding machines are attached to each end of one central main shielding machine so that they can be separated. and a plurality of jet nozzles are installed in recesses between the face plates of the central main shield machine and both end main shield machines. 5. In a multi-core parallel arbitrary cross section shielding machine configured by installing multiple shielding machines, two main shielding machines are installed together, and an over cutter is installed at the edge of the face plate of the main shielding machine. A multi-core parallel arbitrary cross-section shield machine characterized by being installed so that it can protrude or recess from the edge of a face plate. 6. In a multi-core parallel arbitrary cross-section shielding machine configured by installing a plurality of shielding machines, one main shielding machine and two both-end main shielding machines are installed together, and the main shielding machine and A multi-core parallel arbitrary cross-section shielding machine, characterized in that an overcutter is installed at the edge of the faceplate of a main shielding machine at both ends so that it can protrude or recess from the edge of the faceplate.