KR20120005680A - Multi-step tunnel constructing method using pilot tunnel - Google Patents

Abstract

PURPOSE: A tunnel construction method of a multi-stage excavation mode applying a pilot tunnel is provided to improve work efficiency and to improve the stability of a tunnel. CONSTITUTION: A tunnel construction method of a multi-stage excavation mode applying a pilot tunnel is composed like next. A pilot tunnel(51) is dug in the longitudinal direction using a blasting mode. The excavation works is performed after excavating a part of the pilot tunnel. The residual tunnel portions(52,53) reaching the cross section excluding the pilot tunnel is divided to be excavated in the longitudinal direction of a tunnel.

Description

Multi-Step Tunnel Constructing Method Using Pilot Tunnel}

The present invention relates to a tunnel construction method, and more particularly, to a tunnel construction method of a multi-stage excavation method using a pilot tunnel that brings a shortening of the construction period of the entire tunnel and improves work efficiency.

The tunnel is constructed by determining the overall size, such as a round-trip two-lane or four-lane according to the vehicle passing through the interior.

In general, the two-lane round trip tunnel is divided into small cross-section tunnels, and the four-lane round-trip tunnel is divided into large cross-section tunnels. In some cases, the small cross-section tunnel includes two small cross-section tunnels in parallel tunnels. Therefore, one tunnel may be configured as an upline and the other tunnel may be configured as a downline.

On the other hand, as shown in Figure 1, in the case of a conventional large cross-section tunnel, the excavation work is made over a predetermined length (l1) in the longitudinal direction of the tunnel to be constructed through several blasting per day, usually about 2m The entire tunnel construction was carried out through two excavation works. In other words, the excavation was carried out to a length of about 4m per day to complete the entire tunnel.

By the way, in the conventional tunnel construction method, in particular, in the case of large cross section tunnel, there is a problem that the whole construction period of the tunnel takes too long because the excavation section is too short per day.

In order to solve this problem, considering the vibration problem of the ground recently, in order to increase the excavation speed, the tunnel construction method using the TBM is completed by digging the pilot tunnel using TBM and expanding the excavation through blasting around to complete the final tunnel. It is applied to various tunnel sites at home and abroad.

Briefly describing the tunnel construction method using such a TBM as follows.

Conventional TBM tunnel construction method by excavating the center of the tunnel to be constructed using the TBM in the transverse direction to excavate the TBM pilot tunnel by a certain length, and then drills the blast hole for blasting to the ceiling and sides of the TBM pilot tunnel. .

Next, when the drilling operation of the blast hole is completed, charge the gunpowder to the completed blast hole and blast in the planned order to excavate the remaining tunnel portion.

In addition, the interior of the pilot tunnel is gradually enlarged according to such a method. The blasting process is removed until the interior of the tunnel reaches the final large cross section tunnel surface to be constructed. Repeat the work.

After that, again drilling by a certain length using TBM again and repeatedly repeating the above process to complete the entire tunnel.

By the way, the conventional construction method of the tunnel using TBM is to expand the construction after passing through the central portion of the tunnel to be installed pilot tunnel, at this time the excavation speed is slowed, which is delayed until the entire tunnel construction period Resulted.

In addition, the amber buckle produced when the tunnel was blasted was recycled using a separate road pavement or other landscaping facility, but the buff produced by excavation using such TBM has a considerably smaller particle size. As a result, there was a problem that recycling is impossible.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the aforementioned problems and drawbacks of the prior art, and an object of the present invention is as follows.

First, the purpose of the present invention is to provide a tunnel construction method that can shorten the construction period of large section tunnels such as four-lane or more tunnels.

Second, its purpose is to provide a tunnel construction method that can shorten the construction period and increase the recyclability of the cancer bag.

Third, the purpose is to provide a tunnel construction method that can efficiently install the reinforcement facilities for this while improving the stability of the tunnel.

Fourth, the purpose of the present invention is to provide a tunnel construction method that can reduce the occurrence of civil complaints by minimizing damage of the surrounding terrain where the tunnel is constructed.

In order to achieve the above object, the present invention is a step of excavating the pilot tunnel a plurality of times in a blasting manner along the longitudinal direction of the large cross-section tunnel to be constructed and after excavating the pilot tunnel some length, It provides a tunnel construction method of the multi-stage excavation method applying a pilot tunnel comprising a step of digging along the longitudinal direction of the tunnel dividing the remaining tunnel portion to at least one end surface in cross section other than the pilot tunnel.

Here, excavation of the pilot tunnel and excavation of the remaining tunnel portion may be performed in parallel.

The method may further include reinforcing the upper portion of the pilot tunnel for each excavation step of the pilot tunnel.

The step of reinforcing the upper part of the pilot tunnel may include forming a hole in the upper part of the pilot tunnel, installing a grouting reinforcing unit in the formed hole, and grouting construction in the hole in which the grouting reinforcing unit is installed. It may be configured to include.

The grouting reinforcing unit installed in the drilling hole is made of a form in which a steel reinforcing member and a GRP reinforcing member are connected, and the GRP reinforcing member may be installed to be positioned below the large end face tunnel.

The excavation position of the pilot tunnel may be excavated at a position eccentric from the center of the large cross-section tunnel to be constructed.

In addition, when digging the residual tunnel portion in two or more times, excavation of each of the remaining tunnel portions may be performed in parallel.

Referring to the effect of the multi-stage blasting tunnel construction method to which the present invention pilot tunnel configured as described above is as follows.

First, according to the present invention brings the air shortening effect required for the entire construction of the tunnel, which in turn brings the effect of reducing the construction cost.

Second, the excavation of the pilot tunnel can be partly eccentric from the center of the tunnel, so it is possible to construct the tunnel by securing the optimum working environment according to the situation, and also bring a favorable effect in terms of construction period.

Third, since the rock conditions around can be checked while pre-exploring the blasting pilot tunnel, there is an effect that the excavation work of the remaining tunnel portion can be performed stably and the excavation speed of the remaining tunnel portion can be adjusted.

Fourth, since the pilot tunnel is excavated in a blasting manner it is advantageous in the recycling of the arm block.

1 is a perspective view schematically showing a large cross-section tunnel to explain the excavation process of a conventional tunnel;
2 is a front view and a side cross-sectional view showing an excavation process of a pilot tunnel according to the present invention;
Figure 3 is a front and side cross-sectional view schematically showing a state in which the grouting reinforcement unit is installed on top of the pilot tunnel according to the present invention;
4 and 5 are a front view and a side sectional view showing an excavation process of the pilot tunnel according to the present invention;
6 is a front view and a side sectional view showing a state in which a vehicle used in the multi-stage excavation tunnel construction method according to the present invention is installed;
Figure 7 is a side view showing a grouting reinforcement unit used in the tunnel construction method of the multi-stage excavation method according to the present invention;
8 is a side view showing a state in which the grouting reinforcement unit used in the multi-stage excavation tunnel construction method according to the present invention is installed;
9 is a perspective view schematically showing the excavation of the pilot tunnel in a large cross-section tunnel to explain the excavation process of the tunnel according to the present invention; And
10 is a view showing the excavation of the pilot tunnel for the construction of a large cross-section tunnel according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. Note that, in the following description, components that are substantially the same in structure and function and can be handled identically can be identified by the same reference numerals.

2 is a view showing a pilot tunnel excavated in the multi-stage tunnel excavation method according to the present invention.

As shown, according to the tunnel excavation method of the multi-stage excavation method using the pilot tunnel of the present invention, the pilot tunnel 51 is excavated over a predetermined section along the longitudinal direction of the tunnel to be constructed inside the large cross-section tunnel.

In this case, a blasting method such as a general tunnel construction method will be used, and the excavation work may be performed up to a predetermined length through a plurality of operations per day.

In general, the excavation of the pilot tunnel 51 according to the present invention is a small diameter excavation, the operation is carried out at an excavation speed of about 7m or more twice in about 3.5m at a time used in the conventional two-lane tunnel excavation Can be done.

Next, as shown in FIG. 3, the upper section of the drilled pilot tunnel 51 is reinforced by the grouting reinforcing unit 100 and grouting.

Here, grouting refers to stabilizing the ground by injecting a predetermined grouting material such as cement into the ground for the purpose of leakage prevention or soil stability in civil works.

Then, a separate rod-shaped grouting reinforcement unit is installed, which will be described later in detail and description.

Next, after the above reinforcement work is completed, as shown in the accompanying FIG. 4, the remaining tunnels 52 and 53 are excavated to the outside of the pilot tunnel 51 up to the inner surface of the large cross-section tunnel. It goes through the steps.

At this time, the excavation work of the pilot tunnel 51 is performed in parallel. In other words, the excavation work of the pilot tunnel may be performed simultaneously with or alternately with the excavation work of the remaining tunnel portion.

On the other hand, the residual tunnel portion can be divided into a plurality of sections in the excavation, that is, as shown in the accompanying Figures 4 and 5, the cross section of the remaining tunnel portion 52, 53 in the cross section around the pilot tunnel 51 Excavation can be made over.

4 and 5 illustrate the excavation by configuring the remaining tunnel portion other than the pilot tunnel in two stages, and the excavation operation may be performed by dividing three or more sections in cross section.

And, in the tunnel construction method of the multi-stage excavation method according to the present invention, in order to improve the work efficiency when the excavation of the pilot tunnel and the excavation of the remaining tunnel portion are performed in parallel, as shown in FIG. 81) It is preferable to use the electric and water supply vehicle 80 provided at the same time and the water supply unit 82 to supply electricity and water for the excavation work.

In this case, the electric and water supply vehicle 80 may be easily made both forward / backward to enable more efficient working operation when the excavation work through the blasting in the tunnel.

On the other hand, the grouting reinforcement unit 100 is exposed to the inner surface of the large tunnel tunnel when excavation of the remaining tunnel portions 52 and 53, which are parts other than the pilot tunnel 51, and the grouting reinforcement unit is located in the remaining tunnel. It is desirable to be excavated together at the excavation of the part.

In particular, in the case of the inner surface of the large-section tunnel to make the inner surface smooth by using a separate cutting device, the grouting reinforcement unit located above the tunnel for the reinforcement of the upper part of the tunnel is made of a strong steel (steel), The reinforcing unit located in the cutting device is preferably made of a material that is cut together when cutting the inner surface of the tunnel.

To this end, as shown in Figure 7 attached, the grouting reinforcement unit 100 used in the tunnel of the multi-stage excavation method applying the pilot tunnel of the present invention is inserted into each of a plurality of drilling holes drilled in the ground and a plurality of along the longitudinal direction The dog is configured to include a reinforcing member (10, 20) connected in a divided form, the reinforcing member (10, 20) is made of a rod-shaped having a predetermined length, respectively, steel reinforcing member (10) ) And GRP (Glass Reinforced Plastic) material GRP reinforcing member 20 is preferably used.

That is, as shown in the construction of the tunnel, the GRP reinforcing member 20 is located from the upper ground of the tunnel to be installed toward the lower construction of the tunnel, the rest of the steel reinforcing member 10 is Reinforcement unit 100 is used is configured by a plurality of connected,

At this time, the steel reinforcing member 10 has a form in which a plurality is connected, each steel reinforcing member 10 or the GRP reinforcing member 20 and the steel reinforcing member 10 are all connected by a compression connection module 110. It is preferable that the form becomes.

The compression connection module 110 serves to connect the respective reinforcing members (10, 20) and at the same time serves to be fixed in a state in which the tensile force is operating in the drilling hole for installing the grouting reinforcement unit.

The grouting reinforcement unit formed as described above, as shown in the accompanying FIG. 8, constructs the plurality of drilling holes (H) to reach a pre-designed tunnel inner part from the upper side of the tunnel to be constructed, and the subsequent construction of the tunnel A drilling operation is performed such that some of the grout reinforcing units of the invention in particular the GRP reinforcing members 20 are positioned inwardly.

Next, in the perforated hole H, the tunnel is located, that is, a part of the tip of the perforated hole H is filled with the resin or the quick grouting material 130.

Here, the resin or quenching grouting material 130 is made of a material that is hardened in a quick time, the filling depth is filled to a depth enough to insert a part of the GRP reinforcing member 20 of the grouting reinforcement unit 100. .

Next, a step of inserting the grout reinforcing unit 100 into the GRP reinforcing member 20 is inserted into the drilling hole H filled with the resin or the quick grouting material as described above.

Then, when the filled resin or the fastening grouting material is hardened, the front end portion of the grout reinforcing unit 100, that is, the GRP reinforcing member 20 is fixed to the inside of the drilling hole, is installed to partially protrude to the ground side. Pull the steel reinforcing member 10 to the outside to achieve a state in which the tensile force acts throughout the grouting reinforcement unit (100).

Then, the perforated hole (H) is finally filled with a general grouting material, and performs the operation of fixing the steel reinforcing member 10 located at the outermost to the ground using a fixing cap or fixing bolts.

When the installation and grouting reinforcement work of the grouting reinforcement unit is completed through the above process, the grouting reinforcement unit 100 inside the drilling hole H is provided in each compression connection module along its length direction. Compression force is applied to each section where the spring is located.

In addition, when the grouting material is hardened around the grouting reinforcing unit 100, the ground also forms a state in which the compressive force acts up and down, and thus the upper and lower tunnels are constructed to maintain a stable structure. do.

In this case, since the GRP reinforcing member 20, which is made of glass-reinforced synthetic fiber, is positioned as a portion of the remaining tunnel portion to be excavated, cutting and forming to form the tunnel inner surface as well as the excavation of the remaining tunnel portion and In the case of the cutting operation, the operation is made easier than in the case of the conventional steel reinforcement member.

Referring to the effect of the tunnel excavation method of the multi-stage excavation method applying the present invention pilot tunnel configured as described above are as follows.

As shown in FIGS. 2 to 5, the pilot tunnel 51 is first excavated, and then the remaining tunnel portions 52 and 53 are excavated in multiple stages.

That is, according to the present invention, as shown in the accompanying FIG. 9, the pilot tunnel 51 is first excavated, and since the pilot tunnel is made with a smaller cross section compared to the entire large cross-section tunnel, the excavation length l2 is used during the day's work. Excavation is possible with considerable length.

In particular, while the pilot tunnel 51 is being excavated, it is possible to grasp the characteristics of the rock to excavate the surrounding rock, that is, the remaining tunnel portions 52 and 53 to be excavated, that is, the type and hardness of the rock.

On the other hand, the excavation work of the pilot tunnel 51 and the remaining tunnels 52 and 53 is possible in parallel, but the pilot tunnel 51 is pre-excavated and the remaining tunnels are excavated so that the remaining tunnels 52 and 53 are excavated. It is possible to control the degree of blasting or the progress of excavation for the excavation of the), and the stable operation is possible in terms of the efficiency of the equipment, and eventually the excavation work is faster than when the tunnel is excavated with a large area at one time Construction period can be shortened.

Furthermore, the type of rock can be identified in advance through the pre-drilling operation of the pilot tunnel, so that the installation of the grouting reinforcement unit can be installed in an appropriate number and arrangement according to the surrounding rock. Economics can be secured by adjusting the number of units installed.

In addition, according to the present invention, since the pilot tunnel is excavated by the blasting method, a large size of a female bag may be generated, and thus, a problem of recycling a female bag that is a problem when digging a TMB can be solved.

Meanwhile, FIG. 10 is a view illustrating a pilot tunnel in a large cross-section tunnel in a tunnel construction method of a multistage excavation method according to another embodiment of the present invention.

That is, as in another embodiment of the present invention, the entire tunnel can be completed by excavating the remaining tunnel part after excavating the pilot tunnel 61 at a position eccentrically from the situation.

As such, when the pilot tunnel is excavated to the eccentric position from the center of the tunnel to be constructed, it can be usefully applied depending on the hardness of the rock located on the cross section of the terrain in which the tunnel is constructed. In other words, when there is some hard rock, the pilot tunnel is avoided and the remaining tunnel part can be excavated using various blasting methods while securing a wide internal working space and excavation range. And the excavation work will also bring the effect that can be kept to the maximum.

In the case of another embodiment of the present invention, the installation of the other grouting reinforcement unit and the excavation of the remaining tunnel portion are the same as the above-described embodiment, and thus a detailed description thereof will be omitted.

As described above, the preferred embodiments of the present invention have been described, and the fact that the present invention can be embodied in other specific forms in addition to the above-described embodiments without departing from the spirit or scope thereof has ordinary skill in the art. It is obvious to them. Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and thus, the present invention is not limited to the above description and may be modified within the scope of the appended claims and their equivalents.

51,61: pilot tunnel 52,53: remaining tunnel part
80: electricity and water supply vehicle 81: electricity supply
82: water supply unit 100: grouting reinforcement unit

Claims (7)

Digging the pilot tunnel a plurality of times in a blasting manner along the longitudinal direction of the large-section tunnel to be constructed; And
Excavation is performed after the pilot tunnel is partially excavated, and the excavation along the longitudinal direction of the tunnel is divided into at least one cross section of the remaining tunnel portion reaching a large cross section other than the pilot tunnel;
Tunnel construction method of a multistage excavation method applying a pilot tunnel configured to include a. The method of claim 1,
Excavation of the pilot tunnel and the excavation of the remaining tunnel portion is a tunnel construction method of the multi-stage excavation method to which the pilot tunnel is applied. The method of claim 1,
Every excavation step of the pilot tunnel,
And a step of reinforcing the upper part of the pilot tunnel. The method of claim 3,
Reinforcing the upper portion of the pilot tunnel,
Forming a hole in the upper part of the pilot tunnel;
Installing a grouting reinforcement unit in the formed hole; And
Grouting construction in the drilling hole in which the grouting reinforcement unit is installed;
Tunnel construction method of a multistage excavation method applying a pilot tunnel, characterized in that configured to include. The method of claim 4, wherein
The grouting reinforcement unit installed in the drilling hole,
The steel reinforcing member and the GRP reinforcing member is formed in the form,
The GRP reinforcing member is a tunnel construction method of the multi-stage excavation method applying a pilot tunnel, characterized in that the installation is located so as to be located below the large cross-section tunnel. The method of claim 1,
Excavation position of the pilot tunnel,
A multi-stage excavation tunnel construction method using a pilot tunnel, characterized in that excavation to the eccentric position from the center of the large-section tunnel to be constructed. The method of claim 1,
When the excavation of the residual tunnel by dividing the excavation in two or more times, excavation of each of the remaining tunnels is performed in parallel.

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