KR101460495B1 - Method for tunnel geological investigation using boring excavation - Google Patents

Abstract

More particularly, the present invention relates to a method for surveying tunnel geology by drilling by a drilling rig, and more particularly, to a method for surveying tunnel geology using a drilling rig with a camera installed in a large-diameter boring hole formed on a tunnel surface, And it is possible to precisely grasp the geology and condition of the untreated tunnel front surface in advance to select the tunnel blasting mode and the charge amount.
The present invention is characterized in that a step S100 of forming a large diameter boring hole for boring a large diameter boring hole 10 toward the front side of the film surface at a height of 0.3-1.7 m above the bottom surface of the tunnel;
A step S200 of inputting a moving probe device 100 into which the camera 102 mounted on the boring hole 10 is inserted;
A boring ball photographing step (S300) of photographing the inside of the boring hole (10) while moving the motion search apparatus (100) forward;
A monitor observation step (S400) of observing the inside of the boring hole (10) photographed by the mobile survey apparatus (100) with the external monitor (200);
(S500), which is located in front of the tunnel surface, through the interior of the boring hole (10) identified by the monitor (200)
A plurality of wheels 105 are installed at a lower portion of the body 101 so that the mobile search apparatus 100 can be moved in the step S200, A camera 102 is installed on the front surface of the body 101 so as to photograph the inside of the boring hole 10 while the camera 102 is rotated 360 degrees The camera 102 is mounted on a head 104 which is adjustable up, down, left, and right,
In the boring ball photographing step S300, the transmission / reception cable 120 is connected to the control device 150 for adjusting the moving and surveying device 100 and the moving and scanning device 100, and the control device 150 is connected to the receiving cable 121 The tunnel 200 is connected to the monitor 200 and the control device 150 controls the monitor 200 so as to drive and photograph the moving surveying apparatus 100. The tunnel geology Survey method.

Description

METHOD FOR TUNNEL GEOLOGICAL INVESTIGATION USING BORING EXCAVATION FIELD OF THE INVENTION [0001]

More particularly, the present invention relates to a method for surveying tunnel geology by drilling by a drilling rig, and more particularly, to a method for surveying tunnel geology using a drilling rig with a camera installed in a large-diameter boring hole formed on a tunnel surface, And it is possible to precisely grasp the geology and condition of the untreated tunnel front surface in advance to select the tunnel blasting mode and the charge amount.

In designing a tunnel, it is difficult to fully grasp the geological information at the depth of tunnel excavation. Therefore, it is inevitable to design the tunnel by predicting the geological condition by rough information obtained from surface survey or drilling survey.

Therefore, the occurrence of unexpected geological conditions during construction can occur during construction of the tunnel, and if proper and rapid on-site response is not performed, collapse and collapse of the tunnel wall will result in enormous loss of life and property .

Although it is essential to respond promptly to the geological conditions of the tunnel wall at the tunnel construction site, in most cases the objective information is insufficient, and the type, spacing, and thickness of the supporting stiffener In fact, it is a reality that the site design is made during the construction which gives a change to it, and the information management and analysis about it is practically discouraged.

The inadequacies of securing and managing the information of the geologic rock mass during the construction process is a major obstacle to the effective maintenance of the tunnel after completion of the construction.

Japanese Patent Application Laid-Open No. 2002-288180 and Japanese Patent Application Laid-Open No. 2002-227582, attempts have been made to synthesize information on the site as a database, but due to the fact that the collection of the surface information is not out of the existing methods, Site analysis can not be performed and the site design during construction is still dependent on the subjective judgment of the field engineer.

In order to solve the above-described problems, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a tunneling apparatus for boring a large- It is an object of the present invention to provide a method of surveying tunnel geology by drilling of an open pit which can grasp precise geological survey and status of a site where a tunnel is to be excavated.

Also, it is an object of the present invention to provide a method for surveying tunnel geology by a drilling rig, which is capable of repairing cracks, groundwater leakage, and weathering zone of a rock in a boring hole.

In order to achieve the above-mentioned object, the present invention provides a method of forming a preliminary bore boring hole (S100) for boring a large-diameter boring hole (10) toward a front side of a buried surface at a height of 0.3 to 1.7 m above the bottom surface of a tunnel

A step S200 of inputting a moving probe device into which the moving probe device 100 equipped with the camera 102 is inserted into the boring hole 10,

A boring ball photographing step S300 for photographing the inside of the boring hole 10 while moving the motion locating apparatus 100 forward;

A monitor observation step (S400) of observing the inside of the boring hole (10) photographed by the mobile survey apparatus (100) with the external monitor (200)

(S500), which is located in front of the tunnel surface, through the interior of the boring hole (10) identified by the monitor (200)

A plurality of wheels 105 are installed at a lower portion of the body 101 so that the mobile search apparatus 100 can be moved in the step S200, A camera 102 is installed on the front surface of the body 101 so as to photograph the inside of the boring hole 10 while the camera 102 is rotated 360 degrees The camera 102 is mounted on a head 104 which is adjustable up, down, left, and right,

In the boring ball photographing step S300, the transmission / reception cable 120 is connected to the control device 150 for adjusting the moving and surveying device 100 and the moving and scanning device 100, and the control device 150 is connected to the receiving cable 121 The tunnel 200 is connected to the monitor 200 and the control device 150 controls the monitor 200 so as to drive and photograph the moving surveying apparatus 100. The tunnel geology And to a survey method.

The present invention can grasp the geology and condition of the site where the tunnel is to be excavated in a short time, and can select the tunnel blasting form, the excavation distance, and the charge amount through the detected geology and condition, Can be increased.

In addition, it is possible to confirm the cracks, groundwater outflow, weathering zone distribution section, etc. generated in the boring hole through the mobile surveying device equipped with the distance measuring device, and repair the crack occurrence, groundwater outflow, It is effective to increase the efficiency and prevent the tunnel collapse in advance.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a flowchart showing an embodiment of a method for surveying tunnel geology by drilling by a drill rig according to the present invention; FIG.
Fig. 2 is a state of a boring ball formed on a tunnel surface according to the present invention; Fig.
Figure 3 is a state diagram of an apparatus for boring shot according to the present invention;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order to facilitate a person skilled in the art to which the present invention pertains.

FIG. 1 is a flow chart showing an embodiment of a tunnel geological survey method according to the present invention. FIG. 2 shows a state of a boring ball formed on a surface of a tunnel according to the present invention. (S100), a step of injecting a moving probe (S200), and a boring ball photographing step (S200). The boring ball photographing step Step S300, monitor observation step S400, and lipid condition confirmation step S500.

In the step S100 of forming the preliminary borehole, a large-diameter boring hole 10 is bored toward the front of the surface of the tunnel for performing the geological survey using a boring machine (not shown).

At this time, it is preferable that the height of the boring hole 10 is 0.3 to 1.7 mm (lower position than the conventional one) from the bottom of the tunnel to the top. The rock forming the tunneling surface of the tunnel is weakest against the tensile force, , And it is the strongest for compressive strength.

Therefore, when the tunnel is blasted by using the boring hole 10 as a free surface after the geological investigation of the tunnel through the boring hole 10, the upper rock of the free surface receives tensile force (gravity) toward the free surface direction So that blasting can be easily performed even with a small blasting force (small charge amount).

Here, the height of 0.3 to 1.7 m of the boring hole 10 is the lowest position for forming the boring hole 10, considering the scale and weight of the real equipment.

In the moving probe insertion step S200, the mobile scanning device 100 equipped with the camera 102 is inserted into the boring hole 10 formed in the boring hole forming step S100.

A plurality of wheels 105 are installed on a lower portion of the body 101 so as to allow movement of the mobile surveying apparatus 100. In both sides of the body 101, Respectively.

A camera 102 is installed in front of the body 101 of the mobile search apparatus 100 to photograph the inside of the boring hole 10. The camera 102 is installed on a front surface of the body 101, And is mounted on a head 104 that rotates the camera 102 up, down, left, and right.

In the boring-ball photographing step S300, the camera 100 installed in the moving-probe apparatus 100 photographs the inside of the boring hole 10 while moving the moving-image-search apparatus 100 forward.

The control unit 150 for adjusting the moving image sensing apparatus 100 and transmitting the image captured by the camera 102 of the moving image sensing apparatus 10 to the monitor 200 is connected to the moving image sensing apparatus 100, And the controller 150 is connected to the monitor 200 by the receiving cable 121 to check the movement of the mobile surveying apparatus 100 to the monitor 200 installed outside, The apparatus 150 can adjust the movement of the moving and scanning apparatus 100 forward and backward and the rotation of the camera 102 so that the inside of the boring hole 10 can be photographed up, down, left, and right.

In the monitor observation step S400, a screen photographed by the camera 102 of the mobile survey apparatus 100 is observed by a monitor 200 installed outside.

The screen of the inside of the boring hole 10 photographed by the camera 102 of the mobile surveying apparatus 100 is transmitted to the control apparatus 150 through the transmission and reception cable 120. In the control apparatus 150, An operator can observe the inside of the boring hole 10 through the monitor 200 installed on the outside by allowing the monitor 200 to display a photographing screen in the apparatus 100. [

In the geological condition checking step (S500), the operator observes the inside of the boring hole (10) displayed on the monitor (200) to check the lipid condition in front of the tunnel surface,

Cracks generated in the inside of the boring hole 10, outflow of ground water, distribution interval of the weathering zone of the rock, etc., while checking the inside of the boring hole 10 through the monitor 200, , The amount of loading, and the tunnel reinforcement method.

The distance measuring device 107 is installed on the lower side of the front part of the body 101 and the moving distance of the moving surveying device 10 is measured by the distance measuring device 107 through the monitor 200 ), Thereby allowing the operator to roughly grasp the locations of cracks, groundwater outflow, weathering zone distribution sections of the rocks, etc. generated in the boring holes 10.

However, when cracks, groundwater leakage, and weathering zone distribution of rocks are wide in the tunnel eruption expected period, burden due to tunnel explosion, cracks, and underground water leaked are incompletely buried and toxic gas generation and blasting efficiency are reduced In order to prevent the problem of tunneling due to the weathering zone distribution interval and the like, a crack, which is outside the boring hole 10 on the surface of the tunnel surface and confirmed through the movement surveying apparatus 100, The small borehole (20) is drilled in accordance with the groundwater outflow and the distribution of the weathering zone of the rock bed, and repair agent is injected into the perforated small borehole (20) to repair cracks, groundwater outflow, weathering zone distribution section of rock mass.

In addition, 30 to 50% by weight of aluminate cement having excellent waterproof performance due to low porosity and permeability, 30 to 50% of bentonite for preventing sedimentation of other compositions, and the like for repairing cracks, groundwater outflow, weathering- 3% to 6% by weight of methylcellulose which improves the physical properties of the repairing agent by increasing the adhesion of the repairing agent and improving the moisture retention; 3 to 6% by weight of sodium naphthalenesulfonate which can improve the durability of the repairing agent; It is preferable to mix 5 to 10% by weight of dibutyl phthalate to increase elasticity and prevent cracking.

The tunnel geological survey method using the above-mentioned drilling of the tunnels can confirm the exact geological condition and the state of the tunnel excavation site (inner head, direction of the river, strength, weathering etc.) It is possible to select the reinforcement method in advance, and it is possible to perform maintenance and reinforcement work depending on the situation, which is advantageous in that blasting efficiency and safety can be improved when the tunnel is blasted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It will be appreciated that embodiments are possible. Accordingly, the true scope of the present invention should be defined by the appended claims.

10-Boring Ball 20-Small Borehole
100-Moving Exploration Device 101-Body
102-camera 104-head
105-wheel 106-lighting
107-Distance measuring device 120-Transmitting / receiving cable
121-Receiving cable 150-Control device
200-Monitor

Claims (4)

A step S100 of forming a large diameter boring hole at a height of 0.3 to 1.7 m above the bottom surface of the tunnel and drilling the large diameter boring hole 10 toward the front side of the tunneling surface;
A step S200 of inputting a moving probe device 100 into which the camera 102 mounted on the boring hole 10 is inserted;
A boring ball photographing step (S300) of photographing the inside of the boring hole (10) while moving the motion search apparatus (100) forward;
A monitor observation step (S400) of observing the inside of the boring hole (10) photographed by the mobile survey apparatus (100) with the external monitor (200);
(S500), which is located in front of the tunnel surface, through the interior of the boring hole (10) identified by the monitor (200)
A plurality of wheels 105 are installed at a lower portion of the body 101 so that the mobile search apparatus 100 can be moved in the step S200, A camera 102 is installed on the front surface of the body 101 so as to photograph the inside of the boring hole 10 while the camera 102 is rotated 360 degrees The camera 102 is mounted on a head 104 which is adjustable up, down, left, and right,
In the boring ball photographing step S300, the transmission / reception cable 120 is connected to the control device 150 for adjusting the moving and surveying device 100 and the moving and scanning device 100, and the control device 150 is connected to the receiving cable 121 The control unit 150 adjusts the motion of the mobile unit 100 by checking the monitor 200 and driving and photographing the mobile unit 100,
A distance measuring device 107 may be installed below the front portion of the body 101 to detect a crack occurrence position in the boring hole 10, a ground water outflow position, and a weathering strip distribution position of the rock mass ,
After confirming the occurrence of cracks in the boring hole 10, the outflow of ground water, and the distribution of the weathering zone of the rock, a small borehole 20 was drilled at a location outside the boring hole 10, The repairing agent is injected into the small borehole 20,
The repairing agent is a mixture of 30 to 50 wt% of aluminate cement, 30 to 50 wt% of bentonite, 3 to 6 wt% of methyl cellulose, 3 to 6 wt% of sodium naphthalenesulfonate and 5 to 10 wt% of dibutyl phthalate Tunnel Geological Survey Method by Longitudinal Bore Excavation. delete delete delete

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