JP2004285679A - Shield tunnel and shield tunnel connecting construction method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a shield tunnel and a shield tunnel connecting construction method, simply performing connection in a short time in connecting the shield tunnel and an underground structure. <P>SOLUTION: This shield tunnels T1, T2 are shield tunnels T1, T2 connected to the underground structure S disposed in the periphery. An opening segment 11 in which joint surfaces 12, 12 of both side parts formed in the circumferential directions of the shield tunnels T1, T2 in segments constituting the shield tunnels T1, T2 are increased in width from the inside of the shield tunnels T1, T2 toward the outside of the shield tunnels T1, T2 is disposed in contact with the underground structure S. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a shield tunnel and a connection method of the shield tunnel.
[0002]
[Prior art]
Conventionally, when a station building a is constructed in a subway, for example, two shield tunnels T, T are juxtaposed, and then the inside of the tunnel T is reinforced with a shoring b, the surrounding ground is improved, and two tunnels from the ground are improved. Excavation was performed between the tunnels T and T, and an unnecessary segment of the shield tunnel T was removed and connected while building a station building (underground structure) a in the excavation space (FIG. 5).
In addition, as another method, a steel plate is hung over the upper and lower portions of the two tunnels T, T arranged side by side, and a chemical solution is injected into the surrounding ground to excavate a connection portion and remove a segment, and the station building a is constructed. There is also a construction method (for example, see Patent Document 1).
[0003]
[Patent Document 1]
JP, 2002-115485, A
[Problems to be solved by the invention]
The conventional shield tunnel and the method of connecting the shield tunnel described above have the following problems.
<B> Once the segments connected in a ring shape cannot be easily removed from the shield tunnel simply by cutting the bolts connecting the segments, a part of the segment is cut and the cut portion is removed. It was necessary to remove the segment using it. Therefore, removing the segments required a lot of time and effort, which was uneconomical.
<B> Even the segment to be removed is uneconomical because it uses the same expensive material as the segments of other permanent structures.
<C> If the tunnel is already in operation, it will not be possible to secure the tunnel structure when removing unnecessary segments because it is impossible to assemble the tunnel.
[0005]
[Object of the invention]
SUMMARY OF THE INVENTION The present invention has been made to solve the above-described conventional problems, and in connecting a shield tunnel and an underground structure, a segment that can be easily removed in a short time to connect a shield tunnel and an underground structure. An object of the present invention is to provide a connection method for a tunnel and a shield tunnel.
Another object of the present invention is to provide a shield tunnel and a connection method of the shield tunnel which are excellent in cost performance by manufacturing a segment of a removed portion at a low cost in connection with an underground structure.
Another object of the present invention is to provide a shield tunnel and a shield tunnel connection method capable of constructing and connecting an underground structure without affecting the service even when the tunnel is in use. .
The present invention achieves at least one of these objects.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, the shield tunnel of the present invention is a shield tunnel for connecting to an underground structure arranged around the shield tunnel, wherein the shield tunnel is included in a segment constituting the shield tunnel. An opening segment in which the joint surfaces of both sides formed in the circumferential direction of the opening are widened from the inside of the shield tunnel to the outside of the shield tunnel is arranged so as to be in contact with the underground structure. It is assumed that.
Here, the underground structure is a structure constructed along a shield tunnel, and refers to, for example, a station building or a station facility that is constructed for each fixed section. Underground structures do not necessarily need to be completed but include those under construction.
[0007]
Further, the shield tunnel of the present invention is characterized in that, in the above-described shield tunnel, a support for forming a chord is provided on the inner wall of the arc-shaped shield tunnel including the opening segment.
Here, a chord is a line segment connecting two points on a circle, and in the present invention, a chord is constructed by connecting two points on a tunnel wall having a substantially circular cross section. .
For example, a wall or a pillar can be adopted as the support.
[0008]
Further, the shield tunnel connection method of the present invention is a shield tunnel connection method for connecting the shield tunnel with an underground structure adjacent to the shield tunnel using the shield tunnel, wherein the opening segment Constructs the shield tunnel so as to be in contact with the planned position of the underground structure, removes the opening segment from the underground structure side, and makes the inner space of the shield tunnel and the underground structure continuous. It is characterized by being connected by.
[0009]
Further, the shield tunnel connection method of the present invention is a shield tunnel connection method for connecting the shield tunnel with an underground structure adjacent to the shield tunnel using the shield tunnel, wherein the opening segment Constructing the shield tunnel so as to be in contact with the planned position of the underground structure, constructing the support in the shield tunnel, removing the opening segment from the underground structure side, The inner space of the tunnel and the underground structure are connected continuously.
[0010]
Embodiment 1 of the present invention
Hereinafter, Embodiment 1 of the present invention will be described with reference to the drawings.
This embodiment is an embodiment in which an underground structure S is constructed between two shield tunnels (T1, T2) having a circular cross section arranged side by side, and both T1, T2, S are connected.
[0011]
<B> Construction of shield tunnel A shield excavator is started from a shaft not shown in the figure, and a shield tunnel right part T1 and a shield tunnel left part T2 are constructed side by side.
As the shield excavator for constructing the shield tunnels T1 and T2 (hereinafter, referred to as tunnels), a known excavator including a cutter for excavating the ground, a hood portion, a garter portion, a propulsion jack, and the like can be used. .
[0012]
<B> Construction of tunnel body (general part)
The tunnels T1 and T2 are formed by joining segments 10 each having an arc-shaped cross section in a circular direction with bolts or the like to form a ring body, and joining the ring bodies in the axial direction of the tunnels T1 and T2.
One ring body includes a plurality of normal segments 10 and one key segment 13.
The shape of the ordinary segment 10 is such that joint surfaces formed in the circumferential direction of the tunnels T1 and T2 are formed toward the centers of the tunnels T1 and T2, and are formed to have the same length along the axial direction of the tunnels T1 and T2. ing. Further, the joint surfaces formed in the circumferential direction of the tunnels T1 and T2 are formed to have irregularities in cross section, and these are meshed with each other so as not to bite into the tunnels T1 and T2.
[0013]
<C> Construction of tunnel frame (connection between underground structure and shield tunnel)
In the present invention, as shown in FIG. 1, an opening segment 11 is arranged in addition to the normal segment 10 in the arc portions of the tunnels T1 and T2 where the tunnels T1 and T2 and the underground structure S are expected to be in contact. That is, the opening segment 11 is arranged so as to appear in a digging hole excavated vertically downward from the ground toward the tunnels T1 and T2.
The shape of the opening segment 11 is formed by widening the joint surfaces 12, 12 formed on both sides formed in the circumferential direction of the tunnels T1, T2 from the inside to the outside of the tunnels T1, T2. For this reason, the opening segment 11 does not bite into the tunnels T1 and T2, and is more closely adhered to the segments 10 and 10 on both sides by receiving an external force, so that a water stopping effect can be expected.
In addition, the concave and convex portions provided on the joint surface of the ordinary segment 10 are not necessarily required for the opening segment 11.
Since this opening segment 11 is removed at the time of connection with the underground structure S, the material and the like are not particularly limited as long as the structure of the tunnel can be maintained until the connection with the underground structure S. .
The length of the opening segment 11 in the tunnel axis direction is the same as that of the normal segment 10.
[0014]
In this embodiment, only one opening segment 11 is arranged in the axial direction of the tunnel. However, when the connection length in the tunnel axial direction between the underground structure S and the tunnels T1 and T2 is long, the tunnel T1 is not used. , T2, a plurality of opening segments 11 may be arranged continuously.
Normally, when constructing a tunnel, the joint surfaces in the circumferential direction of the segments are connected while shifting the position in the tunnel circumferential direction toward the tunnel axial direction, but when a plurality of opening segments 11 are arranged. Is shifted in the range that appears on the contact surface 14 with the underground structure S (FIG. 2).
Thus, a ring body is constructed by combining the normal segment 10, the opening segment 11, and the key segment 13.
[0015]
<D> After constructing the connection tunnels T1 and T2 between the shield tunnel and the underground structure, excavating from the ground to between the two tunnels T1 and T2, and constructing the underground structure S in the space. Build a drilling space.
The size of the excavation space is such that it collides with the side walls of the two tunnels T1 and T2, or at least circumscribes the outer walls of the tunnels T1 and T2. At this time, when the excavation space excavated vertically downward from the ground hits the walls of the tunnels T1 and T2, the excavation hole excavates along the peripheral surfaces of the tunnels T1 and T2.
[0016]
An opening segment 11 appears in the excavated space.
The bolt connecting the opening segment 11 and another segment is cut, and the opening segment 11 is pulled out to the underground structure S side. Since no uneven portion is formed on the joint surface 12 of the opening segment 11, the joint can be easily removed. Further, since the opening segment 11 has the joining surfaces 12, 12 formed in the circumferential direction of the tunnels T1, T2 widened outward, a strong joining force between adjacent segments as in the conventional segment. It can be easily and simply removed in a single time, just by cutting the bolt.
When the opening segment 11 is removed, the inner cavities of the tunnels T1 and T2 and the excavation space continue. In the excavation space, the underground structure S is constructed simultaneously with or after the excavation.
[0017]
<E> Enlargement of the opening to the underground structure inside the shield tunnel After the opening segment 11 is removed, the segments around the portion are removed, and the connecting surface of both spaces is expanded to a required size.
Then, the terminal treatment of the junction between the underground structure S and the tunnels T1 and T2 is performed.
In this work, if the collapse of the tunnels T1 and T2 is feared due to a decrease in the structural strength of the tunnels T1 and T2, the tunnels T1 and T2 may be removed from the inside of the tunnels T1 and T2 or the underground structure S as necessary. Reinforce T2.
[0018]
In addition, a segment corresponding to a removal range excluding the opening segment 11 is connected in advance by using, for example, an insert type bolt and a bolt box so that the segment can be separated along the range, so that the segment can be easily separated. If so, the connection between them can be performed more easily and in a shorter time. In this way, the removed segments can be reused as high-quality scrap, since the segments are not particularly cut using fire or the like.
[0019]
Then, a rectangular station building formed by a floor slab, a frame, a slab, a middle pillar, and the like of the station building is constructed in the excavation space.
The cross-sectional shape of the shield tunnels T1 and T2 of the present embodiment as viewed from the front is not limited to a circular one, but may be a rectangular or horseshoe-shaped tunnel. In this case as well, the opening segment 11 is arranged at the contact portion with the underground structure S in the tunnel body to perform the operation.
[0020]
Embodiment 2 of the present invention
Hereinafter, other embodiments will be described. In the description, the same portions as those in the first embodiment are denoted by the same reference numerals, detailed description thereof will be omitted, and two tunnels arranged in parallel will be described. The description will be made using the tunnel T1 arranged on the left side of T1 and T2.
[0021]
In the present embodiment, as shown in FIG. 3, a support 20 that forms a chord is provided on the inner wall of the arc-shaped shield tunnel T including the opening segment 11.
The support 20 secures the stability of the structure after connection of the shield tunnel T and the underground structure S, during construction, or both, and the support 20 is, for example, a wall or a column. In this embodiment, a wall is constructed.
The length of the support 20 in the tunnel T axis direction is, for example, constructed over a range where the underground structure S and the shield tunnel T are in contact with each other, and the position of the support 20 in the tunnel T does not violate the construction limit. Position.
When the wall is provided continuously in the axial direction of the tunnel T and is constructed as a so-called partition, the inner space of the shield tunnel T is separated into a wide space and a narrow space formed on the underground structure S side. . Therefore, even when the large space portion of the shield tunnel T is used, the connection work between the shield tunnel T and the underground structure S corresponding to the narrow space portion can be performed.
In the case of constructing a building underground, there are many situations in which a tunnel T must be constructed in advance as a site problem or construction procedure, and in such a case, this embodiment is a particularly useful construction method. Become.
Further, after the connection between the shield tunnel T and the underground structure S is completed, a space is provided in the wall at predetermined intervals to penetrate the front and back of the wall, so that the remaining portion is connected as a pillar and connected. Can also be used.
The material of the support body 20 does not need to be the same as the segment forming the shield tunnel T, and may be formed of another member.
[0022]
When the support 20 is provided, since the support 20 serves as a part of the structure, the segment 14 to be removed is made of a low material structure, and the area 14 is formed thin as shown in FIG. You may. With this configuration, the manufacturing cost of the shield tunnel T can be reduced, and the overall construction cost can be further reduced.
[0023]
In order to easily install the support 20 in the shield tunnel T, for example, after protruding portions 21 and 21 are provided on the inner wall surface of the tunnel T so as to face each other (FIG. 3), the support 20 is provided therebetween. 20 (removal part 22) may be fitted.
Further, the present invention does not affect the control of the attitude of the shield including rolling in order to construct a shield tunnel having a D-shaped cross section, and is an economical construction method in which a normal construction method is sufficient.
[0024]
【The invention's effect】
The shield tunnel and the method of connecting the shield tunnel of the present invention are as described above, and the following effects can be obtained.
<A> In the shield tunnel of the present invention, in the segments constituting the shield tunnel, joint surfaces on both sides formed in the circumferential direction of the shield tunnel include an opening segment whose width increases from the inside to the outside of the shield tunnel. Because of the arrangement, the segments can be easily and quickly removed, and the two structures can be connected.
<B> In addition, when a support forming a chord is provided on the inner wall of the arc-shaped shield tunnel including the opening segment, the structure of the shield tunnel is stabilized. In addition, the manufacturing cost of the shield tunnel can be reduced by forming the segment of the portion to be thin, so that it is economical.
<C> In addition, it is economical because the connection work with the underground structure can be performed while the tunnel is in operation.
[Brief description of the drawings]
FIG. 1 is a perspective view of a shield tunnel according to a first embodiment of the present invention.
FIG. 2 is a sectional view taken along line II-II of FIG.
FIG. 3 is a partial cross-sectional view of Embodiment 2 of the shield tunnel.
FIG. 4 is a cross-sectional view of a shield tunnel in which a segment of a removed portion is made thin.
FIG. 5 is an explanatory view showing a conventional connection construction method between an underground structure and a shield tunnel.
[Explanation of symbols]
10 Normal segment 11 Opening segment 12 Joint surface 13 Key segment 20 Support 21 Projecting portion S Removal section S Underground structure T Shield tunnel

Claims (4)

It is a shield tunnel for connecting with the underground structure arranged around,
Among the segments constituting the shield tunnel, joint surfaces on both sides formed in the circumferential direction of the shield tunnel include an opening segment that widens from the inside of the shield tunnel to the outside of the shield tunnel, Characterized by being arranged in contact with the structure,
Shield tunnel. In the shield tunnel according to claim 1,
A support forming a chord is provided on the inner wall of the arc-shaped shield tunnel including the opening segment,
Shield tunnel. Using the shield tunnel according to claim 1, in a shield tunnel connection method for connecting the shield tunnel with an underground structure adjacent to the shield tunnel,
Constructing the shield tunnel so that the opening segment is in contact with the planned location of the underground structure,
The opening segment is removed from the underground structure side, and the inner space of the shield tunnel and the underground structure is connected and connected continuously,
Connection method of shield tunnel. Using the shield tunnel according to claim 2, in a shield tunnel connection method for connecting the shield tunnel with an underground structure adjacent to the shield tunnel,
Constructing the shield tunnel so that the opening segment is in contact with the planned position of the underground structure, and constructing the support in the shield tunnel,
The opening segment is removed from the underground structure side, and the inner space of the shield tunnel and the underground structure is connected and connected continuously,
Connection method of shield tunnel.

Images