JP2008075328A - Base isolation and water cut-off structure of vertical shaft joint part - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a base isolation and water cut-off structure of a vertical shaft joint part and a tunnel to prevent a ground state from being changed by an earthquake in a joint part of a segment and a pit mouth after a shield machine passes in the pit mouth of start and arrival vertical shaft of the shield tunnel. <P>SOLUTION: In an entrance device installed in the pit mouth B of the vertical shaft A at start and arrival time of the shield tunnel, entrance packings 1 to be attached to a surface C of an internal wall in the pit mouth B are attached to at least two sections in the pit mouth B across an adequate interval between them, this entrance device has a seal groove (1) 3 communicating with an outer face in the peripheral direction of shield tunnel of the segment D assembled between the entrance packings 1 on the outer face and a seal groove (2) 4 communicating in the peripheral direction of shield tunnel on the surface C of the internal wall in the pit mouth B of the vertical shaft A between the entrance packings 1, and an elastic sealing material 51 is filled into a cavity part 5 formed by a section between the entrance packings 1 and the seal grooves (1) 3 and (2) 4. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

The present invention relates to a seismic isolation and water stop structure between a propulsion pipe or segment of a propulsion method or a shield method and a shaft joint, and mainly in an entrance device installed at the entrance of a shaft when starting and reaching a shield tunnel It relates to the seismic isolation and water stoppage structure of the shaft joint used.

Seismic isolation and water stoppage are implemented at the junction of the shaft and segment where the shield tunnel starts and reaches.

BACKGROUND OF THE INVENTION
Concrete is placed and held in the gap between the shield tunnel and the shaft of the shaft, but due to ground deformation due to earthquakes, etc., the joint between the tunnel and the tunnel is damaged and the space is opened, and earth and sand and groundwater are in the shaft. There is a problem of inflow.

[Conventional technology]
In order to improve this, conventionally, the pit of this type of shaft is filled with an elastic injection material in the gap between the pit and the pipe blocked by the entrance packing, and the peripheral edge of the pipe and the gap of the mine are sealed. In addition, it has been disclosed that it is possible to cope with ground fluctuations caused by earthquakes and the like, and to prevent inflow of earth and sand and groundwater from the gaps between the wellhead and the conduit and the concrete wall surface (for example, Patent Document 1). reference).

JP 2002-167738 A (for example, FIG. 5)

However, in the seismic isolation waterproofing method and its structure around the sluice wellhead, the entrance packing is a single row at the wellhead, and the elastic filler becomes insufficiently filled due to deviation from the natural ground side of the wellhead. Due to the smooth contact surface, there is a problem that reliability of seismic isolation and water stoppage is poor.

The present invention has been made in view of such circumstances, and the problem to be solved is the start of the shield tunnel and the wellhead of the reaching shaft, and the seismic isolation between the segment after passing the shield machine and the gap of the wellhead An object of the present invention is to provide a seismic isolation and water stop structure for shaft joints that can further improve the reliability of water and water stop.

(1) In the entrance device installed at the entrance of the shaft when starting and reaching the shield tunnel, the entrance packing attached to the inner wall surface of the entrance is attached to at least two locations of the entrance with appropriate intervals. A seal groove that communicates with the outer surface of the shield tunnel in the circumferential direction of the segment assembled between the entrance packings, and a space formed between the entrance packings and the seal groove is filled with an elastic sealing material. It is characterized by that.

According to the seismic isolation and water stop structure of the shaft joint according to the present invention, even when the shield machine passes through the step due to the outer diameter difference between the shield machine and the segment and the step of the middle collapse of the shield machine, etc. There are at least two entrance packings annularly arranged on the front and back of the inner wall surface, so that water can be stopped, and after the shield machine starts and arrives from the shaft and passes, By filling an elastic seal material from an injection pipe or a segment grout injection pipe arranged in the wellhead into a limited space shielded from the outside formed by the seal groove, the elastic seal material can be deviated from the ground. In addition to preventing and satisfying filling, the ends of each structure can be damaged due to relative displacements such as expansion and contraction of shafts and tunnels during shearing. Strangely it can be kept apart.

As the elastic sealing material, an asphalt emulsion, urethane, silicon rubber, rubber-based material, or the like that is elastically solidified after injection is preferable.

Therefore, according to this, even if there is a step when passing through the shield machine, it is possible to prevent leakage of muddy water and groundwater from the wellhead, and after passing through the shield machine, the wellhead can be seismically isolated and water-stopped. Safety and durability are improved.

(2) In the entrance device installed at the entrance of the shaft when starting and reaching the shield tunnel, the entrance packing attached to the inner wall surface of the entrance is attached to at least two locations of the entrance with appropriate intervals. And a seal groove that communicates with the outer surface of the shield tunnel in the circumferential direction of the segment assembled between the entrance packings, and a seal groove that communicates with the circumferential direction of the shield tunnel on the inner wall surface of the shaft of the shaft between the entrance packings. It is preferable that the space formed between the entrance packings and the sealing groove is filled with an elastic sealing material.

According to the seismic isolation and water blocking structure of the shaft joint according to the present invention, the inner wall surface of the wellhead has a seal groove on the outer surface of the segment between at least two entrance packings, and the inner wall surface of the wellhead is also sealed. Since there is a groove, the elastic seal material does not deviate from the ground, and the presence of both seal grooves increases the volume of the elastic seal material, such as the installation distance and height. Earthquake and water stop are possible.

Therefore, according to this, since the seismic isolation and water stop of the wellhead can be performed more reliably, the safety and durability of the structure against the earthquake are improved.

(3) It is preferable that the shield groove has a trapezoidal cross section in the axial direction of the shield tunnel, and the oblique sides facing each other form a tapered portion.

The elastic sealing material filled in the gap formed by the gap between the entrance packings and the seal groove is formed in a wedge shape in cross section due to the presence of the taper portion, so if external water pressure is applied, it is pushed by itself toward the wedge shape. Thus, a so-called self-sealing action in which the contact pressure between the sealing groove and the elastic sealing material is increased.

Further, by arranging the entrance packing at the tapered portions on both sides of the seal groove, the entrance packing is leaned against the tapered portion of the seal groove and comes into close contact therewith.

Therefore, according to this, in addition to seismic isolation, there is a further improvement in the water stoppage.

(4) It is conceivable that an annular tube that can be expanded by fluid injection is provided in a gap formed between the entrance packings and the seal groove.

After filling the gap between the entrance packing and the seal groove with an elastic sealant, inject fluid as necessary to inflate the tube, apply internal pressure to the elastic sealant, and the elastic sealant expands to the seal groove surface. Acts to adhere.

As the fluid injection, asphalt, urethane, silicon, rubber-based materials, etc. that are elastically solidified after injection are preferable.

Therefore, according to this, even if the internal pressure of the elastic sealing material is insufficient due to relative displacement due to an earthquake or the like and water leakage occurs, the water can be easily stopped, so that maintainability is improved.

According to the seismic isolation and water stop structure of the shaft joint of the present invention, the safety and durability of the structure can be improved because the start of the shield tunnel and the reliable seismic isolation and water stop of the well shaft and segment of the reaching shaft are possible. Increased maintenance costs can be reduced.

Hereinafter, a seismic isolation and water stop structure of a shaft joint according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG.1 and FIG.2 is sectional drawing of the seismic isolation and water stop structure of the shaft junction which concerns on embodiment of this invention.

The seismic isolation and water-stopping structure of the shaft joint according to the present embodiment is the entrance device installed at the shaft entrance of the shaft when starting and reaching the shield tunnel. In addition to the well-known water stop structure with the segment, it is configured to have a seismic isolation and water stop structure at the joint between the wellhead and the segment after passing through the shield machine.

Specifically, as shown in FIGS. 1 and 2, the entrance packing 1 attached in a ring shape to the inner wall surface C of the pit B of the shaft A has a packing rubber 11, a fixing bracket 12, and a flap 13 bolted to the inner wall surface C. A tube (1) 16 fixed to the packing rubber 11 and connected to the injection pipe 2 is attached to the inner wall surface C, and the flap 13 is connected to the inside of the wellhead B via a hinge 15. Inclined in the direction, the packing rubber 11 is supported, and the tip portion is in contact with the segment D.

The outer surface D1 of the segment D within the inner wall surface C of the wellhead B has a trapezoidal seal groove (1) 3 communicating in the circumferential direction, and the entrance packing 1 is a tapered portion of the seal groove (1) 3. (1) Attached to two locations in contact with 31.

Further, on the inner wall surface C of the wellhead B, a seal groove (2) 4 having a trapezoidal tapered section (2) 41 communicating in the circumferential direction of the shield tunnel is provided at the edge of the tube (1) 16 of the entrance packing 1 It is provided between the parts.

An injection pipe 2 or a segment grout hole (not shown) is formed in the gap 5 formed between the entrance packings 1, the seal groove (1) 3, and the seal groove (2) 4.

Further, an annular tube (2) 6 that can be expanded by fluid injection connected to the injection pipe 2 is attached to the groove surface of the seal groove (2) 4 of the gap portion 5.

Next, the effect of the seismic isolation and water stop structure of the shaft joint having such a configuration will be described.

When the shield machine starts from the shaft A or reaches the shaft A, the flap 13 inclines toward the inner side of the pit B via the hinge 15 to support the packing rubber 11, and the tip is abutted against the segment D Therefore, a complete sealing effect can be obtained with respect to the internal pressure biased by the packing rubber 11.

After the shield machine starts from the shaft A or reaches the shaft A, the segment D is assembled in the shaft B, and an elastic solidified filler such as silicon (1) is injected from the injection tube 2 to the tube (1) 16 in the gap 5. ) 17 and press the tube (1) 16 to expand.
As a result, the flap 13 inclines inward of the wellhead B via the hinge 15 to support the packing rubber 11, and since the tip is in contact with the segment D, the tube (1 ) A complete sealing effect is obtained for 16 internal pressures.

In addition, by filling and sealing an elastic seal material 51 that is elastically solidified by injecting fluid such as silicon from the injection tube 2 into the gap portion 5, the entrance packing 1, the seal groove (1) 3, and the seal groove (2 The elastic sealing material 51 filled and enclosed in the gap 5 formed by
Since the tube (1) 16 is expanded and the packing rubber 11 is pressure-bonded to the seal groove (1) 3, even if a sufficient pressure is applied to inject and fill the elastic sealing material 51, it is elastic from the entrance packing 1. Since the sealing material 51 can be sufficiently filled and sealed without leaking, the expected volume can be ensured reliably, so that the response of relative displacement such as an earthquake increases, so it works effectively for seismic isolation, Since the cross section is formed in a wedge shape due to the presence of the taper portion (1) 31 and the taper portion (2) 41, when the external water pressure is applied, the contact pressure with the elastic seal material 51 is increased by being pushed in the wedge shape direction. As a result, the self-sealing effect can be obtained.

Further, by arranging the entrance packing 1 in the taper portion (1) 31 of the seal groove (1) 3 of the segment D, the packing rubber 11 is leaned against the taper portion (1) 31 of the seal groove (1) 3 and closely contacts. By doing so, it leads to the response to the relative displacement and the improvement of the water stoppage.

In addition, after filling the gap 5 between the entrance packing 1 and the seal groove (1) 3 and the seal groove (2) 4 with the elastic seal material 51, the wellhead B of the shaft A and the segment D inserted into the well D In the case where water leaks due to relative displacement caused by an earthquake or the like, a filler (2) 61 such as silicon is injected from the injection tube 2 into the tube (2) 6 to inflate the tube (2) 6 to be elastic. The internal pressure is applied to the sealing material 51, and the elastic sealing material 51 expands and acts so as to be in close contact with the seal groove surface and the entrance packing surface. Will increase.

In this case, the material to be injected into the tube (2) 6 is an elastic solidifying material, but does not solidify after the injection, for example, by injecting oil or the like, it becomes possible to adjust the necessary pressure at any time, and water leaks due to an earthquake or the like. Even if this occurs, it is possible to block water leakage by expanding the elastic sealing material 51 by the injection pressure each time by applying an internal pressure.

Note that the present invention is not limited to the illustrated example described above, and is applicable to, for example, the case where the entrance packing is not disposed in contact with the seal groove of the segment, and does not depart from the spirit of the present invention. Of course, various changes can be made within the scope.

In the seismic isolation and water stop structure of the shaft joint of the present invention, the shield machine and the water stop structure between the segment and the wellhead when the shield tunnel starts or arrives from the shaft when the shield tunnel is constructed are sufficiently satisfied. At the same time, after passing through the shield tunnel, the relative displacement between the shaft and pipe due to earthquake etc. is absorbed by the elastic sealant and entrance packing filled with sufficient volume and shape around the pipe with sufficient functionality, and In addition, the elastic sealing material and the entrance packing block the groundwater inflow, and the structure of the seismic isolation and water stop at the time of completion is realized by adding ingenuity to the water stop structure at the time of shield construction, It is extremely useful for shield tunnels in Japan that are prone to ground deformation such as earthquakes.

It is sectional drawing of the seismic isolation and water stop structure of the shaft junction which concerns on embodiment of this invention. It is sectional drawing of the seismic isolation and water stop structure of the shaft junction which concerns on embodiment of this invention.

Explanation of symbols

A ... Vertical shaft B ... Wellhead C ... Inner wall surface D ... Segment D1 ... Outer surface 1 ... Entrance packing 11 ... Packing rubber 12 ... Fixing bracket 13 ... Flap 14 ... Bolt 15 ... Hinge 16 ... Tube (1)
17 ... Filler (1)
2 ... Injection tube 3 ... Seal groove (1)
31 ... Tapered part (1)
4 ... Seal groove (2)
41 ... Taper part (2)
5 ... Cavity 51 ... Elastic sealing material 6 ... Tube (2)
61 ... Filler (2)

Claims (4)

In the entrance device installed at the entrance of the shaft when starting and reaching the shield tunnel,
The entrance packing attached in an annular shape to the inner wall surface of the wellhead is attached at an appropriate interval to at least two locations of the wellhead,
The outer surface in the circumferential direction of the shield tunnel of the segment assembled between the entrance packings has a sealing groove communicating therewith,
A seismic isolation and water stop structure for shaft joints, characterized in that an elastic seal material is filled in a gap formed between the entrance packings and the seal groove. On the inner wall surface of the shaft opening of the shaft between the entrance packings, there is a seal groove communicating in the circumferential direction of the shield tunnel,
2. The seismic isolation and water stoppage structure of the shaft joint according to claim 1, wherein an elastic sealing material is filled in a gap formed between the entrance packings and the seal groove. The seismic isolation and stop of the shaft joint according to claim 1 or 2, wherein the seal groove has a trapezoidal cross section in the axial direction of the shield tunnel, and the opposite oblique sides form a tapered portion. Water structure. In the gap formed between the entrance packings and the seal groove,
An annular tube expandable by fluid injection is attached,
The seismic isolation and water stop structure of a shaft joint according to any one of claims 1 to 3.

Images