KR100977278B1 - The bottom segment and shield tunnel process thereof - Google Patents

Abstract

PURPOSE: A bottom plate segment and a shield method using the same are provided to reduce working time by reducing working processes and to improve work efficiency by reducing costs. CONSTITUTION: A shield method using a bottom plate segment is as follows. A segment ring(10) is installed inside a cave using multiple segments(20) and bottom plate segments. Excavated materials and the segments are transferred to the outside or inside the cave. A ground wire(122) is installed in a mounting groove(120) of the segment ring.

Description

Base plate segment and shield method using the same

The present invention relates to a bottom plate segment and a shielding method, and more particularly to a bottom plate segment having a flat top surface, thus omitting a process for installing a conventional moving surface, and easily moving a sleeper and a rail after the segmenting installation. The present invention relates to a bottom plate segment and a shield method using the same, which can be installed in such a way that the overall work period and cost can be reduced, thereby improving work efficiency.

In general, the shield method is a state-of-the-art method using a shield excavator, which can be called a huge super excavator, is an advanced method than the conventional NATM method.

Such a shielding technique moves forward while digging a shield excavator having a cutter wheel at its tip in the ground, and installs one segment ring in which a plurality of segments are coupled to the excavated cave to form an outer wall of the tunnel.

After a certain length of excavation by the shield excavator, the tunnel and the underground structure are constructed by repeating the process of installing a new segment ring at the end of the segment ring.

1 is a view showing a conventional shield method, Figure 2 is a view showing a schematic flow chart of the conventional shield method, Figure 3 is a view showing the installation of the segment and ground line installation.

As shown in the figure, the ground is excavated in the vertical direction to the position where the tunnel is to be formed, and the excavation is started using a shield excavator (not shown) in the horizontal direction at the tunnel formation position.

When the shield excavator excavates a predetermined distance, it is assembled into a tubular segment ring 1 to carry a plurality of prefabricated segments 2 to form an outer wall of the excavated portion.

The segment ring 1 forms the outer wall of the tunnel, and serves to prevent ground subsidence by supporting the excavated portion.

When the segment ring (1) is installed, the shield excavator moves forward again by digging a predetermined distance, and repeats the process of installing a new segment ring (1) in the excavated portion.

At this time, the auxiliary block 3, the sleeper 4 and the rail 5 is installed in the segment ring 1 for the transport of the excavation and materials and the movement of the worker.

Looking at the installation and removal of the rail (5) and installation of the grounding ground (6), as shown in Figures 2 to 3, while installing the segment ring (1) while excavating, each segment constituting the segment ring (1) You must ensure that there is a transport route for transporting restraints and excavations.

In order to secure this transport path, an auxiliary block 3 having a flat top surface is installed on the segment 2 located below the segment ring 1.

The auxiliary block 3 is formed in an arc such that the lower surface thereof corresponds to the upper surface of the bottom segment 2, and the sleeper 4 and the rail 5 are installed on the upper surface to secure the transport path.

When the excavation and segment ring (1) installation is completed by repeating this process, the grounding wire (6) is installed by removing the sleepers (4), the rails (5) and the auxiliary block (3).

After the ground wire 6 is mounted together with the perforated drain pipe 7, the rubble layer 8 filled with gravel or the like is formed, and the flat concrete layer 9 is placed on the upper side of the rubble layer 8 to ground. The installation of the branch line 6 is completed.

At this time, the water flowing in the ground layer is discharged along the pore drain pipe, it is easy to discharge the water contained in the rubble layer (8) to facilitate the concrete layer (9) pouring.

And a separate drain groove is formed on the upper surface of the concrete layer (9) to easily discharge the water flowing between the segment ring (1) of the mantissa.

The poured concrete layer 9 is then used for transport of workers and transportation of materials for further installation and management of the tunnel.

However, when installing the excavation and segment ring (1), it is natural to install the sleeper (4) and the rail (5) by installing a separate auxiliary block (3), but the ground bottom (6) and perforated drain pipe (7) In order to eliminate the auxiliary block (3) in order to lose the process and costs are generated.

This process is the cause of increasing the total air, the resulting cost is further increased, there is a problem that lowers the work efficiency.

Accordingly, the present invention has been made to solve the above problems, the lower surface of the bottom plate segment to form an arc, the upper surface is formed to form a tunnel outer wall can be omitted the process of forming a conventional moving surface. .

In addition, the drainage path may be formed on the upper surface of the bottom plate segment to facilitate the drainage function, as well as to easily install and remove the sleepers, and to form the grounding wire installation hole therein, so that the grounding wire can be easily installed.

As a result of the reduction of the work process, the overall process can be reduced to shorten the working period and the cost can be reduced, and therefore, an object of the present invention is to provide a bottom plate segment and a shield method using the same that can improve work efficiency.

In order to achieve the above object, the present invention provides a shielding method for assembling a plurality of segments to form a tunnel outer wall, and installing a sleeper and a rail to transport materials and excavations to form a tunnel, the bottom of the assembled segment ring The lower surface is formed to form an arc to form a circle with the other segment, the upper surface is formed flat, a pair of drainage passages having a predetermined interval is formed in the longitudinal direction of the tunnel, and the ground wire installation hole and grouting hole is formed inside The upper surface may be provided with the sleepers and rails to transport materials and excavations, and the worker may move. After completion of the outer wall of the tunnel, only the sleepers and rails may be removed, and a ground ground wire may be installed to complete the tunnel.

Preferably, the bottom plate segment is spaced apart at equal intervals based on a center line through which the drainage channel passes through the upper surface center portion, and the grounding wire installation hole is provided on at least one selected bottom surface of the drainage passage, and the grouting hole has a top surface. It penetrates through the lower surface and is located on the center line.

In addition, after the gravel and the ground wire is installed in the ground wire installation port, it is sealed and partitioned from the drainage path.

In addition, the bottom plate segment is spaced apart at equal intervals, respectively, with respect to the center line passing through the center of the upper surface, the grouting hole is perforated to pass through the upper surface and the lower surface is located on the center line, the earthing ground installation device It is perforated in parallel with the center line to communicate with the grouting hole.

In addition, mounting jaws are formed at both ends of the bottom surface of the sleeper, and each of the mounting jaws touches a side located on the outer side of each side of the drainage segment of the bottom plate segment.

In addition, the bottom plate segment is manufactured in a precast manner, and is manufactured in advance according to the size of the tunnel to be formed.

In the shield method of assembling a plurality of segments to form a tunnel outer wall, and installing sleepers and rails to transport materials and excavations to form a tunnel, the lower surface forms an arc to form a circle with another segment, and the upper surface is Segment installation step of forming a flat bottom, a pair of drainage passages having a predetermined interval on the upper surface in the longitudinal direction of the tunnel, and the bottom plate segment through which the grounding wire installation hole and the grouting hole are formed to form the bottom surface of the segmenting to be assembled And installing a sleeper and a rail on an upper surface of the bottom plate segment, and carrying and installing the excavated material and the respective segments and materials to the outside or the inside of the oyster using the installed rail, and installing and transporting the material and the excavated material. After the transportation and installation of water and materials, the rails and sleepers installed on the bottom plate segment are removed. It includes the grounding ground installation step of installing the grounding ground wire in the existing ground ground installation hole.

Further, the drainage passages of the bottom plate segment are spaced at equal intervals based on the centerline passing through the upper center portion, and the grounding wire installation hole is provided below the bottom of any one or more selected ones of the drainage passages, and the grouting hole has an upper surface and a lower surface. Perforated to penetrate through and positioned on the center line, the ground line installation step, after removing the sleeper and the rails, the ground line mounting step for mounting the ground line to the ground line installation port, the ground so that the ground line is not visible from the outside Filling step to form a gravel layer by filling the gravel layer in the branch line installation, and a concrete sealing the step of forming the bottom surface of the drainage passages, as well as the drainage passages by the concrete pouring the upper side of the gravel layer.

And the drainage passage of the bottom plate segment is spaced at equal intervals, based on the center line passing through the upper surface center portion, the grouting hole is penetrated through the upper surface and the lower surface is located on the center line, the ground wire installation port is in communication with the grouting hole Perforated parallel to the center line so as to, the ground wire installation step, the lead wire insertion step of connecting a lead wire to one end of the ground ground wire, and inserting the lead wire into the ground ground wire installation port, through the lead wire through the ground wire installation hole It includes a grounding wire mounting step for passing through the grounding ground, and a sealing step for sealing the grounding ground installation hole and the grouting hole is mounted on the grounding ground.

In addition, the bottom plate segment is manufactured in a precast manner, and is manufactured in advance according to the size of the tunnel to be formed.

And in the excavation and material transport and installation step, the mounting jaw is formed on both ends of the bottom surface of the sleeper, each mounting jaw is fitted in contact with the side located on the outer side of each side of the bottom plate segment.

As described above, according to the bottom plate segment and the shield method using the same according to the present invention, the upper surface is formed to be flat, after installation, to easily install and remove the sleepers and rails so that the operator can move or easily transport the material, etc. Can be.

In particular, the process of filling the upper side of the conventional lower segment with crushed stone and forming a moving surface with concrete can be omitted, thereby reducing the work process.

In addition, through the grounding wire installation hole formed in each bottom plate segment, the grounding ground wire can be easily installed, and the sleeper can be easily installed and dismantled in the drainage path, thereby reducing the work time.

Accordingly, it is a very useful and effective invention that can shorten the overall working air, and can reduce the cost by shortening the air, thereby improving the working efficiency.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

In addition, the present embodiment is not intended to limit the scope of the present invention, but is presented by way of example only, and various modifications may be made without departing from the technical gist of the present invention.

4 is a view showing the installation state of the bottom plate segment according to the present invention, Figure 5 is a view showing a schematic flow chart of the shield method using the bottom plate segment according to the present invention, Figure 6 according to the flow chart of FIG. 7 is a view showing a working process, Figure 7 is a view showing a bottom plate segment according to the present invention, Figure 8 is a flow chart schematically showing a method of installing a ground wire to the bottom plate segment according to the present invention, Figure 9 is a view 8 is a view showing the grounding ground installation according to the flow chart of Figure 8, Figure 10 is a view showing another embodiment of the bottom plate segment in accordance with the present invention, Figure 11 FIG. 12 is a view illustrating a grounding ground installation state in the bottom plate segment in the order of FIG. 11, and FIG. 13 illustrates the installation of sleepers and rails in the bottom plate segment according to the present invention. It is time limit drawing.

As shown in the figure, the bottom plate segment 100 forms an arc such that the lower surface 102 forms a circle with the other segment 20, and the upper surface 104 is formed flat, with a pair of drainages having a predetermined interval. 110 is formed in the tunnel longitudinal direction.

In addition, the ground branch installation unit 120 and the grout ball 130 are formed inside the bottom plate segment 100 to form a bottom portion of the segment ring 10 to be assembled, and the upper surface of the sleeper 200 and the rail 210. Optionally installed, the material and excavation can be transported and moved by workers.

Looking at the shield method using the bottom plate segment 100, as shown in Figure 5 to Figure 6, the segment installation step (S10) and the excavation and material transport and installation step (S20) and ground wire installation step (S30) It consists of.

First, the step of excavating the ground in the vertical direction or the excavation in the horizontal direction is the same as the conventional method, it is made before the segment installation step (S10).

In the segment installation step (S10), the segment ring 10 is installed inside the oyster using the plurality of segments 20 and the bottom plate segment 100.

In this case, the bottom plate segment 100 forms an arc so that the lower surface 102 forms a circle with the other segment 20, and the upper surface 104 is formed flat, and a pair of drainage paths 110 having a predetermined interval are tunneled. It is formed in the longitudinal direction, the ground wire installation hole 120 and the grout hole 130 is formed therein.

And the excavation and material transport and installation step (S20) is to transport and install the excavation and each segment (20, 100) and material to the outside or inside of the oyster, the sleeper (top) on the top surface 104 of the bottom plate segment (100) 200 and the rail 210 are installed, and the rail 210 is used to transport and install the excavated material and the like.

Grounding ground installation step (S30) is to install the grounding ground wire 122 in the grounding ground installation hole 120 of each segment ring 10, the rail 210 and sleeper 200 installed in the bottom plate segment 100 Then, the ground ground wire 122 is installed in the ground ground installation hole 120.

Looking at the ground line installation step (S30) as described above in detail, as shown in Figs.

First, as shown in FIG. 7, the bottom plate segment 100 forms an arc such that the bottom surface 102 forms a circle with another segment 20, and the top surface 104 is formed flat, but has a predetermined interval. A pair of drainage paths 110 are formed in the tunnel longitudinal direction.

In addition, the grounding wire installation hole 120 and the grout hole 130 are formed inside the bottom plate segment 100 to form a bottom portion of the segment ring 10 to be assembled, and the upper surface of the sleeper 200 and the rail 210. The installation allows materials and excavations to be transported and moved by workers.

At this time, the drainage path 110 is spaced apart at equal intervals with respect to the center line passing through the central portion of the upper surface 104 of the bottom plate segment 100, and the grounding wire installation hole 120 is formed on any one or more selected bottoms of the drainage path 110. The grouting hole 130 is provided to be penetrated through the upper surface 104 and the lower surface 102 and is positioned on the center line.

As shown in FIGS. 8 to 9, the ground branch installation step S30 in the bottom plate segment 100 includes a ground branch mounting step S31, a filling step S32, and a sealing step S33.

Grounding ground mounting step (S31) is to mount the grounding ground 122 to the grounding ground installation hole 120 of the bottom plate segment 100, the sleeper 200 and the rail (200) on the upper surface 104 of the bottom plate segment 100 The ground branch 122 is mounted in a state in which 210 is removed.

And filling step (S32) fills the gravel layer 124 by filling the gravel in the ground line installation port 120 so that the mounted ground line 122 is not visible from the outside through the drainage path (110).

The sealing step (S33) is to form the concrete layer 126 by placing the upper side of the gravel layer 124 to form a concrete ground duct 120, as well as the drainage passage 110 and the partition, and to form the bottom surface of the drainage passage. .

The state passed through such a ground wire installation step (S30) is as shown in FIG.

Meanwhile, as shown in FIGS. 10 to 12, the bottom plate segment 100 ′ of another embodiment and a shield method using the same are illustrated.

As shown in FIG. 10, the bottom plate segment 100 ′ may form an arc such that the bottom surface 102 ′ forms a circle with another segment 20, and the top surface 104 ′ may be formed flat. A pair of drainage paths 110 'with a spacing is formed in the tunnel longitudinal direction.

In addition, the grounding wire installation hole 120 'and the grout hole 130' are formed inside the bottom plate segment 100 'to form a bottom portion of the segment ring 10, and the upper surface of the sleeper 200 and the rail ( By installing 210, the material and the excavation can be transported and moved by the worker.

At this time, the drainage path 110 'is spaced apart at equal intervals from the center line passing through the center portion of the upper surface 104' of the bottom plate segment 100 ', and the grouting holes 130' are spaced apart from the upper surface 104 '( 102 ') and is located on the centerline.

In addition, the grounding wire installation hole 120 ′ is formed to communicate with the grouting hole 130 ′ in parallel with the center line in the bottom plate segment 100 ′.

As shown in FIG. 11, the ground lead installation step S30 'is installed in the bottom plate segment 100' as the leader line insertion step S31 ', the ground lead mounting step S32', and the sealing step S33 '. It is composed.

The leader line inserting step (S31 ') allows the lead wire 124' to pass through and pass through the ground lead wire installation hole 120 '. The lead wire 124' is connected to one end of the ground lead wire 122 ', and the lead wire ( 124 'is inserted into the ground wire installation hole 120'.

In addition, the ground lead mounting step (S32 ') is to mount the ground lead 122' to the ground lead installation 120 ', and passes through the lead wire 124' mounted on the ground lead installation 120 ' The ground wire 122 'is mounted on the branch wire installation hole 120', and then the lead wire 124 'is removed.

Sealing step (S33 ') is to seal the grounding ground installation hole 120' and the grouting hole 130 'is mounted, the grounding ground installation hole 120' and grouting hole 130 ' ) To form a sealing layer 126 ′ to prevent water from entering.

The ground ground 122 'installation state by the ground ground installation step S30' is as shown in FIG.

On the other hand, as shown in Figure 13, look at the installation of the sleeper 200 and the rail 210 to the bottom plate segment 100, the mounting jaw 202 is formed on both ends of the bottom surface of the sleeper 200, respectively.

Each mounting jaw 202 of the sleeper 200 is fitted to each of the drainage passages 110 of the bottom plate segment 100, the sleeper ( 200 is fixed to the bottom plate segment 100.

This can omit a process by omitting the use of a separate fixing member for fixing the sleeper, thereby reducing work time and cost.

In addition, the sleeper 200 can be easily attached and detached to the bottom plate segment 100, so that after the shield tunnel is formed, the sleeper 200 and the rail 210 can be easily installed and removed, as well as reducing work time and cost. .

Naturally, the sleeper 200 is also applicable to the bottom plate segment 100 ′ of another embodiment.

In addition, the bottom plate segments 100 and 100 ′ are prefabricated and transported to the site according to the size of the tunnel to be formed by the precast method, thereby shortening the work process.

1 is a view showing a conventional shield method,

2 is a view showing a schematic flowchart of a conventional shield method,

3 is a diagram showing the installation of the segment and ground wire installation,

4 is a view showing an installation state of the bottom plate segment according to the present invention,

5 is a schematic flowchart of a shield method using a bottom plate segment according to the present invention;

6 is a view showing a work process according to the flow chart of FIG.

7 is a view showing a bottom plate segment according to the present invention,

8 is a flowchart schematically showing a method for installing grounding conductors in a bottom plate segment according to the present invention.

9 is a view showing the grounding ground installation according to the flow chart of FIG.

10 is a view showing another embodiment of a bottom plate segment according to the present invention,

FIG. 11 is a flowchart schematically illustrating a method for installing grounding lines in a bottom plate segment of FIG. 10.

FIG. 12 is a view illustrating a ground line installation state in a bottom plate segment in the order of FIG. 11;

13 is a view showing the installation of sleepers and rails in the bottom plate segment according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10: segment 100, 100 ': bottom plate segment

102, 102 ': Bottom surface 104, 104': Top surface

110, 110 ': Drainage 120, 120': Grounding earth installation

122, 122 ': ground wire 124: gravel layer

126: concrete layer 124 ': leader line

126 ': sealing layer 130, 130': grouting ball

Claims (11)

In the shielding method for forming a tunnel, in the segmenting having a plurality of segments provided for installing sleepers and rails to transport materials and excavations, A plurality of segments form a bottom portion of the assembled segment ring, the lower surface is formed arc to form a circle with the other segment, the upper surface is formed flat, a pair of drainage channels having a predetermined interval is formed in the tunnel longitudinal direction, Grounding wire installation hole and grouting hole is formed inside, The upper surface is to install the sleepers and rails to transport materials and excavations and workers can move, and after completion of the tunnel outer wall, only the sleepers and rails can be removed, and the ground ground wire can be installed to complete the tunnel, The bottom plate segment formed in the bottom portion of the segment, The drainage passages are spaced apart at equal intervals, respectively, based on the centerline passing through the upper surface center portion, and the grounding branch installation hole is provided on at least one selected bottom surface of the drainage passage, and the grouting hole is perforated to penetrate the upper and lower surfaces of the drainage passage. Located on the center line, after installing the gravel and ground line in the ground line installation port, the bottom plate segment characterized in that it is partitioned from the drainage. delete delete In the shielding method for forming a tunnel, in the segmenting having a plurality of segments provided for installing sleepers and rails to transport materials and excavations, A plurality of segments form a bottom portion of the assembled segment ring, the lower surface is formed arc to form a circle with the other segment, the upper surface is formed flat, a pair of drainage channels having a predetermined interval is formed in the tunnel longitudinal direction, Grounding wire installation hole and grouting hole is formed inside, The upper surface is to install the sleepers and rails to transport materials and excavations and workers can move, and after completion of the tunnel outer wall, only the sleepers and rails can be removed, and the ground ground wire can be installed to complete the tunnel, The bottom plate segment formed in the bottom portion of the segment, The drainage passages are spaced apart at equal intervals, respectively, based on the center line passing through the upper surface center portion, and the grouting holes are penetrated through the upper surface and the lower surface, and are positioned on the center line, and the ground line installation tool is in communication with the grouting hole. A bottom plate segment characterized in that it is perforated in parallel with the. The method according to claim 1 or 4, Mounting jaw is formed on both ends of the bottom surface of the sleeper, each mounting jaw is characterized in that the bottom plate segment is inserted in contact with the side located on the outer side of each side of the drainage segment of the bottom plate segment. The method according to claim 1 or 4, The bottom plate segment is manufactured in a precast manner, the bottom plate segment characterized in that it is manufactured in advance according to the size of the tunnel to be formed. In the shield method of assembling a plurality of segments to form a tunnel outer wall, and install a sleeper and a rail to transport materials and excavation to form a tunnel, The lower surface forms an arc to form a circle with another segment, the upper surface is formed flat, a pair of drainage channels having a predetermined interval on the upper surface is formed in the longitudinal direction of the tunnel, the ground plate installation hole and the grouting hole through the bottom plate A segment installation step of forming segments at the bottom of the assembled segment ring; Installing a sleeper and a rail on an upper surface of the bottom plate segment, and carrying and installing the excavated material and each segment and material to the outside or the inside of the oyster using the installed rail, and installing and transporting the material; And After the transport and installation of the excavation and the material is finished, the shield method using a bottom plate segment comprising a ground line installation step of removing the rails and sleepers provided in the bottom plate segment, and install a ground line in the ground line installation port . The method of claim 7, wherein The drainage passages of the bottom plate segment are spaced at equal intervals with respect to the centerline passing through the center of the upper surface, and the grounding wire installation hole is provided below the bottom of any one or more selected ones of the drainage passages, and the grouting hole penetrates the upper and lower surfaces. Perforated but located on the centerline, The ground wire installation step, After removing the sleeper and the rail, the ground wire mounting step of mounting the ground wire to the ground wire installation port; A filling step of forming a gravel layer by filling gravel in the grounding wire installation port so that the grounding wire is not visible from the outside; And Shielding method using the bottom plate segment comprising a sealing step of forming the bottom surface of the drainage passage as well as the drainage passages and partitions by placing concrete on the gravel layer. The method of claim 7, wherein The drainage passages of the bottom plate segment are spaced at equal intervals with respect to the center line passing through the center of the upper surface, and the grouting hole is penetrated to penetrate the upper and lower surfaces, and is located on the center line, so that the ground branch installation hole is in communication with the grouting hole. Perforated parallel to the centerline, The ground wire installation step, A lead wire insertion step of connecting a lead wire to one end of the ground lead wire and inserting a lead wire into the ground lead installation hole; A ground wire holding step of passing a ground wire to the ground wire installation hole through the lead wire; And A shield method using a bottom plate segment comprising a sealing step of sealing the ground ground wire installation hole and the grouting hole is mounted. The method of claim 7, wherein The bottom plate segment is manufactured by a precast method, the shield method using a bottom plate segment, characterized in that the pre-fabrication according to the size of the tunnel to be formed. 8. The method of claim 7, wherein in the excavation and material transport and installation step, Shielding method using a bottom plate segment, characterized in that the mounting jaw is formed on both ends of the bottom surface of the sleeper, each of the mounting jaw is in contact with the side located on the outside of the side of each drainage channel of the bottom plate segment.

Images