KR101294241B1 - Probe drilling geotechnical evaluation system attached to tunnel boring machine for predicting forward geology and tunnel construction apparatus and method using thereof - Google Patents

Abstract

PURPOSE: A horizontal boring device for predicting geological features at the front mounted on a tunnel boring machine (TBM) is provided to allow a user to predict the geological features at the front with a boring investigation and to predict the geological features at the front at real time by showing the inside of a boring hole with images. CONSTITUTION: A horizontal boring device (20) for predicting geological features at the front mounted on a TBM comprises a main frame (21), a boring unit (22), a first guide (23), a second guide (24), a chain belt (25), a mounting unit (26), a driving motor, and a control unit. The main frame forms a main body of the horizontal boring device. The boring unit is installed on the main frame in order to be moved forward and backward, and a rod is mounted on the boring unit in order to excavate a boring hole. The first guide is installed at the front of the main frame in order to guide the rod. The second guide is installed at the front of the first guide in order to support the rod. The chain belt moves the boring unit forward and backward in the main frame. The mounting unit supports the horizontal boring device, and the horizontal boring device is simultaneously mounted on a tunnel construction device such as a TBM. The chain belt supplies power to drive the chain belt. The control unit generally controls movements of the horizontal boring device and a water pump to supply water pressure in boring.

Description

Probe drilling geotechnical evaluation system attached to tunnel boring machine for predicting forward geology and tunnel construction apparatus and method using Yag}

The present invention relates to a method of excavating a tunnel using a tunnel boring machine (hereinafter, referred to as 'TBM'), and more particularly, to predict the lipid for the advancing direction of the TBM by mounting the TBM. The present invention relates to a TBM-equipped ground evaluation system using advanced boreholes for predicting forward geology, which is configured to proceed with construction.

In addition, the present invention relates to a tunnel boring machine having an advanced borehole ground evaluation system for predicting forward geology, which is configured to predict the geological progress of the TBM in advance and proceed with construction as described above.

In addition, the present invention, as described above, by providing an advanced borehole ground evaluation system for predicting forward geology, the tunnel for constructing the tunnel using a tunnel boring machine configured to predict the geological progress in advance and proceed with construction It is about a construction method.

Conventionally, in the construction method for excavating a tunnel, pilot tunnel excavation is generally carried out by using a drilling equipment called TBM, and then a blast is laterally circumferentially enlarged to expand the diameter of the tunnel. This is widely used.

Here, examples of the conventional technology for the existing TBM as described above, for example, "a direction control method and apparatus of an excavator" as disclosed in Japanese Patent Laid-Open No. 05-25998 (1993.02.02) and Korean Patent Publication There is a "tunnel drilling machine equipped with an impact rig" as disclosed in No. 10-2010-0052400 (2010.05.19.).

More specifically, Japanese Patent Application Laid-Open No. 05-25998 relates to a direction control method and an apparatus of an excavator using a shield body having a tail portion connected to the head portion and the rear portion so as to be bent, in particular, to be constructed. A method and apparatus for controlling the forward direction of an excavator using light beams directed along a baseline, such as the terminal line of a terminal.

In addition, the above-mentioned Korean Patent Publication No. 10-2010-0052400, the bit pressure on the impact device, the electric shock device and the tip of the common pressure to increase the excavation capacity of the existing TBM to excavate the rock by pressure and fracture simply by rotating and driving force only The present invention relates to a tunnel drilling machine equipped with an impact drilling device configured to be excavated at high speed even in a hard rock.

In addition, as an example of the prior art for the existing tunnel construction method as described above, for example, as described in the Republic of Korea Patent No. 10-1224880 (January 16, 2013.) Excavation and expansion blasting construction method and related devices ".

More specifically, the above-described TV excavation and expansion blasting construction method of the Patent No. 10-1224880, the conventional TBM excavation and expansion blasting construction method is a method that can damage the rails and cables while piled on the bottom of the pilot tunnel. There is a problem, and also to solve the problem that the excavation of the pilot tunnel using the TBM is stopped until the buckles accumulated on the floor after the explosive blast completely removed.

To this end, according to the registered Patent No. 10-1224880, drilling a pilot tunnel using a tunnel boring machine (TBM), the step of drilling a transverse or longitudinal blasting hole in the upper half end of the pilot tunnel, Connecting and installing a plurality of upper blasting guards that separate the upper half and the lower half in the pilot tunnel, front and rear, expanding and blasting the upper half of the pilot tunnel using the blasting holes, and Provided are a method of excavating and expanding blasting TVs using a blasting guard and a trolley which includes carrying a bag on the upper blasting guard on a trolley moving to a lower space of the upper blasting guard.

As described above, the construction method using TBM and TBM has been researched and developed in various ways from the past, but the conventional TBM and construction methods using the same, it is difficult to check the excavation cross section by the nature, However, it is not easy to cope with sudden ground changes or groundwater in the excavated ground.

In other words, when excavating a tunnel using TBM, for example, if there is an abnormal ground that was not predicted at the design stage, if the TBM is stopped due to such abnormal ground, the construction is delayed, and accordingly construction cost This increase, in some cases, causes huge losses in time and economy.

Therefore, in order to prevent such a problem in advance, it is very important to predict in advance whether there is an abnormal ground which may be a problem on the progression path of TBM by examining the lipid in front of the TBM before the excavation of the TBM.

Here, as the most representative frontal membrane prediction technology in the TBM method, there is a method of mounting a probe drilling system provided by a so-called TBM equipment manufacturer, but most TBM equipments operated in Korea are recycled TBM equipments. There is a problem that mounting of a probe drilling system provided by a manufacturer is practically difficult.

In addition, the above-described probe drilling system, for example, there is a TBM-mounted probe drilling system of Herrenknecht, Germany, which has a disadvantage in that it is difficult to recover the drilling core with the equipment manufactured to focus on drilling.

In addition, as another example, there is a hollow probe drilling system of Koken Co., Ltd., which is installed and operated in the domestic TBM equipment, but this has a disadvantage in that a lot of time is used during drilling work due to poor drilling ability.

Here, as an advanced drilling method for predicting the ground condition in front of the tunnel excavation surface, a method of recovering the drilling core for accurate ground state grasp and a non-core drilling method using data measured during drilling without recovering the core In addition, it is expected that the application of this drilling exploration technology to the tunnel construction can be effectively used for the prediction of rock characteristics and discontinuities.

Therefore, as described above, in order to solve the problems of the conventional TBM equipment and the tunnel construction method using the same, by installing the advanced drilling equipment for investigating the advanced drilling on the TBM equipment by drilling the front ground and taking a sample, It is desirable to provide a tunnel construction equipment and a tunnel construction method using the same, which are configured to predict the ground condition of the ground, but a device or method that satisfies all such requirements has not been provided.

In addition, as described above, in addition to the installation of advanced drilling equipment for recovering the drilling core, the borehole imaging for imaging the inside of the borehole to predict the ground in front of the membrane even when the recovery core by the drilling equipment is impossible It is desirable to provide TBM equipment and tunnel construction methods using the same, which are capable of predicting geological prediction in real time during drilling, including the system, but there are still no devices or methods that satisfy all such requirements.

[references]

1. "Design of Advanced Drilling and Borehole Imaging System for Predicting TBM Anterior Lipids," Ki-Seok Kim, Jong-Hoon Kim, Hee-Yun Ahn, In-Mo Lee, 2012 Korean Society of Rock Mechanics Spring Conference and Conference Proceedings P131-P140. 2012.03.28.

The present invention is to solve the problems of the prior art as described above, and therefore the object of the present invention, the installation of advanced drilling equipment and boreholes for advanced drilling investigation to be able to predict the lipid in the TBM progress direction by mounting on TBM Providing TBM-equipped ground evaluation system using advanced boreholes for anterior geological prediction, including borehole imaging equipment for real-time anterior geological prediction even when the core is impossible to recover by drilling equipment. I would like to.

Further, another object of the present invention is to provide an advanced borehole ground evaluation system for predicting anterior lipids as described above, and thus, it is possible to predict anterior lipids by an advanced drilling investigation that recovers a core. Even if it is impossible to provide an advanced horizontal drilling apparatus for anterior geological prediction that is configured to enable anterior geological prediction in real time by imaging the inside of the borehole.

In addition, another object of the present invention, by using a tunnel factory with an advanced borehole ground evaluation system for predicting forward geology as described above, of the method using the drilling core and the non-core method without using the drilling core It is to provide a tunnel construction method capable of predicting all forward geology.

In order to achieve the object as described above, according to the present invention, it is mounted on the tunnel construction device including a tunnel boring machine (Tunnel Boring Machine, TBM) for predicting the front geology configured to predict the geological direction ahead of the excavation direction In the TBM mounting ground evaluation system using the advanced borehole, Advanced drilling unit configured to perform a lipid analysis by recovering the drilling core; A borehole imaging unit configured to capture an image inside the borehole to perform lipid analysis in a non-core manner when recovery of the borehole core is impossible; A mounting unit for mounting the advanced drilling unit and the borehole imaging unit to the tunnel construction equipment; A geological analysis unit configured to predict the geology of the excavation direction by performing an analysis operation on the drilling core recovered by the advanced drilling unit and an analysis operation of the image obtained through the borehole imaging unit; And a control unit for controlling the operation of the advanced borehole ground evaluation system as a whole, and the TBM-equipped ground evaluation system using the advanced borehole for anterior geological prediction is provided.

Here, the advanced drilling unit, characterized in that made of the advanced drilling equipment of the top head method capable of impact and rotary drilling irradiation.

The borehole imaging unit may include: a borehole camera equipped with a plurality of cameras to simultaneously record images of the front and side surfaces of the borehole; A monitor for displaying an image captured by the borehole camera; A storage device for storing the image photographed by the borehole camera; And a controller for controlling the shooting of the borehole camera from the outside.

In addition, the borehole imaging unit further comprises a meter counter and a temperature sensor for determining the groundwater characteristics, characterized in that configured to display the information detected by each sensor in the captured image.

Furthermore, the geological analysis unit and the control unit are configured to execute a program for performing an analysis operation on the drilling cores recovered by the advanced drilling unit and an image analysis operation obtained through the borehole imaging unit, to execute the system. It is characterized by consisting of a computer or dedicated hardware provided separately from the outside.

In addition, according to the present invention, the drilling core method for recovering the drilling core to perform the geological analysis to recover the drilling core in order to predict the geological direction ahead of the drilling boring machine including a tunnel boring machine and a field that does not recover the drilling core An advanced horizontal drilling apparatus for predicting anterior lipids configured to enable both core-based lipid analysis, comprising: a mainframe forming a main body of the advanced horizontal drilling apparatus; A perforation part installed to be movable back and forth on the mainframe and mounted with a rod for drilling a borehole; A first guide installed at a front end of the main frame to guide the rod; A second guide installed at a front end of the first guide to support the rod; A chain belt for moving the perforation part back and forth on the mainframe; A mounting part for supporting the advanced horizontal drilling device and mounting the tunnel drilling device; A drive motor for supplying power to drive the chain belt to move the perforation part back and forth on the main frame; A control unit for controlling the overall operation of the advanced horizontal drilling device; A sampler mounted to an end of the rod for collecting the drilling core; And a borehole camera that provides a real-time image of the borehole front and side to determine the geological conditions around the borehole when the recovery of the borehole core is impossible. After the drilling device is installed, the rod is mounted to the perforation part, the drive motor is driven to rotate the rod while advancing the perforation part through the chain belt, so that the first guide and the second guide are rotated. The rod is rotated to move forward to excavate the borehole, and after the borehole excavation, the core is collected through the sampler to perform geological analysis, and when the recovery of the core is impossible, the borehole camera is connected to the sampler. Inserted and carried out on the front and side of the borehole instead Provided is an advanced horizontal drilling apparatus for predicting anterior lipids, characterized in that to perform a lipid analysis by taking a liver image.

Here, the advanced horizontal drilling device is characterized in that it further comprises a water pump for applying water pressure in the drilling direction during drilling.

In addition, the drilling portion, the rod mounting portion on which the rod is mounted; A rotating part provided with a rotating shaft for rotating the rod; A coupling part for slidably coupling the perforation part to the main frame to be movable back and forth through the chain belt; And a mounting groove formed in an intermediate portion of the rotating unit, and is configured to mount the water pump through the mounting groove to apply water pressure in the excavation direction of the rod.

In addition, the advanced horizontal drilling device is characterized in that it is configured to change the bore diameter to enable the recovery of the drilling core of various sizes.

Further, the advanced horizontal drilling device is characterized in that it further comprises a drilling data calculation unit for measuring the various parameters during the drilling operation to calculate the drilling data.

In addition, the borehole camera, the camera body is formed in a cylindrical shape with a concave cutting groove formed in the middle portion; A front lighting unit including a front camera and a plurality of LEDs installed on the front of the camera body; A side lighting unit including a side camera installed on the side of the camera body and at least one LED; It is characterized in that it comprises a cable connection portion installed on the rear of the camera body.

In addition, the borehole camera, a control unit for controlling the shooting of the borehole camera from the outside; And a monitor unit having a monitor and a storage device for displaying and storing an image photographed by the borehole camera.

In addition, the monitor unit, the case is configured in the form of a hard case to be easy to carry and move at the same time protect the inside from an external impact; A monitor installed in the case and displaying an image captured by the borehole camera; And a control panel installed in the case to control operations of the borehole camera and the monitor.

The monitor unit may further include a storage unit installed in the case to store an image photographed by the borehole camera.

In addition, the camera body and the monitor, characterized in that configured to be connected by wire or wirelessly by using a cable through the cable connection.

In addition, the monitor unit may be configured to include two monitors for displaying an image of the front camera and an image of the side camera, or one of the images of the front camera and the image of the side camera with only one monitor or It is characterized in that it is configured to display by switching the display method of the two images at the same time.

The advanced horizontal drilling apparatus further includes a meter counter and a temperature sensor for detecting a groundwater characteristic by detecting a temperature difference due to groundwater movement in a fault or crushing zone, and displaying the measurement of each sensor together in the captured image. It is characterized in that the configuration.

In addition, the advanced horizontal drilling device, through the respective sensors to measure the drilling parameters including the rotational pressure, penetration speed, torque, thrust, depth of the rod to build a database for the drilling parameters, based on the database By calculating the puncture index, characterized in that configured to be able to perform the ground evaluation by the puncture index.

Furthermore, the advanced horizontal drilling device is characterized in that it further comprises an air coupling for forming a hollow cylindrical shape for injecting compressed air to perform a non-coring operation.

Here, the air coupling, the compressed air inlet for injecting compressed air; Bearings respectively located inside both ends; Bearing fixtures for securing each of the bearings; An inner casing formed with two semicircles facing each other at the same interval as the size of the compressed air inlet with respect to the compressed air inlet; And both female threads and male threads formed at both ends thereof, wherein the female threads are connected to the perforations, and the rods and casings are connected to the male threads.

In addition, according to the present invention, in order to predict the lipid ahead of the excavation direction, a tunnel configured to enable both a drilling core method for recovering a drilling core and performing a lipid analysis and a non-core lipid analysis without recovering the drilling core. A construction apparatus is provided, including an advanced horizontal drilling apparatus for predicting forward lipids described above, wherein the tunnel construction apparatus is configured to predict the lipid in the forward direction.

In addition, according to the present invention, in order to predict the lipid ahead of the excavation direction, a tunnel configured to enable both a drilling core method for recovering a drilling core and performing a lipid analysis and a non-core lipid analysis without recovering the drilling core. A construction method comprising the steps of: manufacturing an advanced horizontal drilling apparatus for predicting anterior lipids described above; Mounting the advanced horizontal drilling device implemented in the manufacturing step in a tunnel construction device; Predicting the geological direction ahead in the drilling direction through the advanced horizontal drilling device by using the tunnel factory installed with the advanced horizontal drilling device in the mounting step; And constructing the tunnel by performing excavation using the tunnel factory value according to the result of the geology predicted by the advanced horizontal drilling device in the predicting step. do.

As described above, according to the present invention, the tunnel construction equipment and the tunnel using the same is equipped with the drilling equipment for the advanced drilling investigation on the TBM equipment to predict the ground condition of the front by collecting the sample of the front ground As construction method is provided, it is difficult to check the excavation cross section visually, and it is not easy to cope with sudden ground change or groundwater, and if the TBM is stopped due to abnormal ground, construction is delayed, causing time and economic loss. There was a problem with the conventional TBM equipment and the construction method using the same.

In addition, according to the present invention, in addition to the advanced drilling equipment for recovering the drilling core as described above, tunnel construction equipment including a borehole imaging equipment for imaging the inside of the borehole to enable forward geological prediction in real time during the drilling operation; By providing the tunnel construction method using the same, even when the recovery of the drilling core by the drilling equipment is impossible, it is possible to predict the ground in front of the membrane in real time.

In addition, according to the present invention, as described above, the advanced borehole ground evaluation system for the prediction of the forward geology, including the advanced drilling equipment for recovering the drilling core and the borehole imaging equipment for enabling forward geological prediction in real time during the drilling operation And by providing a tunnel construction apparatus and a construction method having such a system, it is possible to predict both the geology of the drilling core and the non-core method of the front core without using the drilling core, which enables more efficient and accurate prediction.

1 is a block diagram schematically illustrating the overall configuration of a TBM-mounted soil evaluation system using advanced boreholes for predicting anterior lipids according to an embodiment of the present invention.
2 is a side view schematically showing the overall configuration of an advanced horizontal drilling apparatus for predicting forward lipids according to an embodiment of the present invention.
Figure 3 is a perspective view schematically showing the overall configuration of the advanced horizontal drilling apparatus according to the embodiment of the present invention shown in FIG.
4 is a view schematically showing a configuration of a perforation part of the advanced horizontal drilling apparatus according to the embodiment of the present invention shown in FIG.
FIG. 5 is a view schematically showing the overall configuration of a borehole camera system inserted in place of a bore core harvester to provide a real-time image of the geological condition around the borehole.
FIG. 6 is a diagram schematically illustrating an overall configuration of a monitor unit for controlling an operation of the camera main body illustrated in FIG. 5 and displaying a photographed image.
7 is a view schematically showing the overall configuration of the air coupling of the advanced borehole horizontal drilling apparatus for anterior geological prediction according to an embodiment of the present invention.
8 is a flowchart schematically showing the overall configuration of a construction method for constructing a tunnel using a tunnel factory having an advanced borehole ground evaluation system for predicting forward geology according to the present invention shown in FIG. 1.

Hereinafter, with reference to the accompanying drawings, it will be described a specific embodiment of the TBM-mounted ground evaluation system using the advanced borehole for predicting forward geology according to the present invention, a tunnel construction device and a tunnel construction method using the same.

Hereinafter, it is to be noted that the following description is only an embodiment for carrying out the present invention, and the present invention is not limited to the contents of the embodiments described below.

In the following description of the embodiments of the present invention, parts that are the same as or similar to those of the prior art, or which can be easily understood and practiced by a person skilled in the art, It is important to bear in mind that we omit.

That is, the present invention, as will be described later, it is difficult to visually confirm the excavation cross section, and it is not easy to cope with sudden ground changes or groundwater, and when the TBM is stopped due to abnormal ground, the construction is delayed and time and economical In order to solve the problems of the conventional TBM equipment and the tunnel construction method using the same, which causes the loss, advanced drilling equipment for performing geological analysis through drilling core recovery, and non-core even if the recovery core is impossible The present invention relates to a TBM-mounted ground evaluation system using advanced boreholes for anterior lipid prediction, including borehole imaging equipment for imaging the inside of boreholes to enable geological analysis.

In addition, the present invention, as will be described later, by installing the advanced borehole ground evaluation system for the prediction of the geological prediction of the geological prediction of both the method using the drilling core and the non-core method without using the drilling core to the TBM equipment, Tunnel construction device configured to predict the ground in front of the ground by sampling the front ground ground during excavation, and to predict the ground ground through the imaging of the borehole even when the recovery of the drilling core is impossible. It relates to a tunnel construction method used.

Hereinafter, with reference to the accompanying drawings, it will be described in detail with respect to the preferred embodiment of the TBM-mounted soil evaluation system using the advanced borehole for the prediction of forward geological according to the present invention as described above, tunnel construction apparatus and tunnel construction method using the same do.

Here, it should be noted that the present invention is not limited only to the embodiments of the present invention described below, and that various modifications and changes can be applied to various forms in addition to the embodiments described below.

First, referring to FIG. 1, FIG. 1 is a block diagram schematically showing the overall configuration of a TBM-mounted soil evaluation system using advanced boreholes for predicting anterior lipids according to an embodiment of the present invention.

As shown in FIG. 1, the TBM-mounted soil evaluation system 10 using advanced boreholes for predicting forward lipids according to an embodiment of the present invention is broadly divided into advanced drilling units for performing lipid analysis through drilling core recovery. 11 and a borehole imaging unit 12 for imaging the inside of the borehole in order to enable geological analysis in a non-core manner even when the recovery of the borehole core is impossible, and the advanced borehole 11 and the borehole imaging unit 12 described above. ) Is configured to include a mounting portion 13 for mounting the tunnel construction equipment, such as TBM device.

In this case, the system 10 performs an analysis operation on the drilling core collected by the advanced drilling unit 11 and an analysis operation of the image obtained through the borehole imaging unit 12 to predict the lipid in the front. The geological analysis unit 14 and the control unit 15 for controlling the operation of the entire system 10 are further included inside or outside the system 10.

That is, the geological analysis unit 14 and the control unit 15 may be, for example, a computer on which a program configured to enable an analysis operation of a drilling core and a borehole image is executed, or dedicated hardware having such a function. Can be configured.

In addition, in the above-described lipid analysis unit 14 and the control unit 15, each analysis method for performing lipid analysis through a method for analyzing lipids using a drilling core and a non-core system using perforation data without a drilling core. For details on, for example, as described in the reference [1], it will be apparent to those skilled in the art with reference to the documents of the prior art, the detailed description thereof will be omitted here.

That is, in general, the drilling equipment is largely divided into a drilling unit (drilling unit) and a power supply unit (power unit), wherein the drilling unit (feed unit, rotation unit (rotation unit), rod fixing unit (road) It consists of holder and flush pump.

In addition, since the power supply unit is divided into an internal combustion engine and an electric power engine, and has a great influence on the drilling capability of the drilling equipment, an optimal specification should be determined according to the purpose.

More specifically, the feed unit serves to transfer the rod mounted on the rotating unit to the excavation surface by using hydraulic pressure, and is generally connected to the rotating unit and the rod connecting unit.

Here, the rotating part is a part for transmitting the rotational and impact energy of the rod and controlling the penetration energy, and is equipped with a drifter or the like for controlling the rotational speed and the impact energy.

In addition, the rotating part is classified into a hollow type and a top head type according to a method of fixing a rod or a casing. First, the hollow type can be manufactured integrally with the feed part and the rotating part, so that the space in the direction of excavation, such as a miniaturization device and a TBM device, is mainly used. Although suitable for this case, the feed pressure is small and the excavation is made only by the rotational energy, which is advantageous for the recovery of the drilling core, whereas the presence of the gravel layer or the strong rock has the disadvantage of lowering the excavation capacity and difficult to change the bore diameter.

On the other hand, in the top head method, since the rotating part is configured to be located at the tip of the rod, the drilling bore diameter of various sizes can be determined using the coupling, and the drilling ability is improved by applying the rotational energy together with the impact type. The machines are mostly top headed in terms of efficiency and drilling capacity.

That is, in the present invention, as described above, the advanced drilling unit 11 is a method for recovering the core by being equipped with a top head advanced drilling equipment which is equipped with a drifter and capable of impact and rotary drilling irradiation In addition to the simultaneous operation of the non-core system and is designed to increase the drilling rate and core recovery rate for the composite ground.

In addition, when it is impossible to recover the drilling core by the above-described advanced drilling equipment, a borehole imaging system may be applied as an alternative for predicting the front ground of the membrane instead of the drilling core. The borehole imaging system can be broadly divided into a televiewer system using an ultrasonic beam and a system using an optical camera.

Here, the tele viewer system using ultrasonic waves is a system for imaging a signal reflected from an empty wall by using the internal water, which has a disadvantage that the internal water must exist.

In addition, a system using an optical camera is classified into an optical televiewer (OPTV) that analyzes the ground using a high-resolution photographic image, and a borehole camera that grasps the information of the borehole wall with a video.

More specifically, televiewer and OPTV are mainly used to investigate the discontinuous surface distributed in the ground, but it takes a long time for data acquisition and processing, and the measurement system is expensive.

On the other hand, the borehole camera is a system that has been actively operated since the development of the above-described OPTV equipment. By continuously screening the borehole wall, the government can quickly identify the government in the borehole by examining the condition of the casing or the presence of the crushing stand. There is an advantage that can be derived.

In addition, for example, by mounting the front and side cameras may be configured to grasp the ground information in two directions at a time, the recording method of the video quality is lower than the recording method of the still image and the resolution of the image Has the disadvantage of being low.

Recently, however, due to advances in camera and optical technology, video quality and resolution can be provided even more in motion than in the past, so that the borehole camera system is widely used in various fields such as borehole, tunnel construction, piping, and production line inspection. have.

That is, in the present invention, the borehole imaging unit 12 is equipped with a CCD-type camera to be configured as a borehole camera system that simultaneously records images of the front and side of the borehole and provides a real-time image of the geological state around the borehole Can be.

In addition, in a fault or a crushing zone, a temperature difference occurs due to the movement of groundwater. Using this feature, the borehole imaging unit 12 according to the present invention further includes a meter counter and a temperature sensor to grasp the groundwater characteristics. It can be configured to be displayed together in the image.

Here, as described above, in the description of the embodiment of the present invention, the advanced drilling unit 11 is made of a top head advanced drilling equipment capable of operating the core recovery method and the non-core system at the same time. In addition, although the above-described borehole imaging unit 12 is configured as a borehole camera system that provides a real-time image of the front and side of the borehole, the present invention will be described, but the present invention is not limited to this configuration.

That is, in the present invention, for example, the advanced drilling unit 11 may be configured in a manner other than the top head method, and the borehole imaging unit 12 records a still image, not a moving image. It may be configured to, or may be configured to record a moving picture and a still picture at the same time.

Therefore, as described above, it is possible to implement the TBM-mounted soil evaluation system 10 using advanced boreholes for predicting anterior lipids according to an embodiment of the present invention.

In addition, by installing the TBM-mounted ground evaluation system 10 using the advanced borehole for predicting the forward lipid according to the embodiment of the present invention configured as described above in the tunnel construction device, it is possible to predict in advance the lipid in front of the TBM during the tunnel construction We can proceed with construction.

Subsequently, referring to FIGS. 2 to 6, the advanced borehole ground for mounting the TBM-mounted ground evaluation system using the advanced borehole for predicting forward lipids according to the embodiment of the present invention configured as described above to the tunnel construction device. The specific configuration of the evaluation apparatus will be described in detail.

First, referring to FIG. 2, FIG. 2 is an advanced horizontal drilling apparatus configured to install a TBM-mounted ground evaluation system 10 using an advanced borehole for anterior geological prediction according to an embodiment of the present invention in an actual tunnel construction device ( 20 is a cross-sectional view schematically showing the overall configuration of 20).

3, FIG. 3 is a perspective view schematically showing the overall configuration of the advanced horizontal drilling apparatus 20 according to the embodiment of the present invention shown in FIG.

More specifically, the advanced horizontal drilling apparatus 20 according to the embodiment of the present invention, as shown in Figures 2 and 3, the main frame 21 to form the main body of the advanced horizontal drilling apparatus 20, A perforated part 22 installed to be movable back and forth on the main frame 21 and mounted with a rod for drilling a borehole, and a first guide 23 installed at a front end of the main frame 21 to guide the rod. ), A second guide 24 provided at the front end of the first guide 23 to support the rod, and a chain belt 25 for moving the above-mentioned perforations 22 back and forth on the main frame 21. And a mounting portion 26 for supporting the advanced horizontal drilling device 20 and for mounting the advanced horizontal drilling device 20 in a tunnel construction device such as TBM.

Here, the advanced horizontal drilling device 20, although not shown, a drive motor for supplying power to drive the chain belt 25 to move the perforations 22 back and forth on the main frame 21, And a water pump for supplying water pressure during drilling and a controller for overall control of the operation of the advanced horizontal drilling apparatus 20.

In addition, referring to Figure 4, Figure 4 is a view schematically showing the configuration of the rotating portion of the advanced horizontal drilling apparatus according to the embodiment of the present invention shown in FIG.

That is, the perforation part 22 is a perforation part 22 through the rod mounting part 27 to which a rod is mounted, the rotating part 28 provided with the rotating shaft for rotating a rod, and the said chain belt 25. It is configured to include a coupling portion 29 that is slidably coupled to the main frame 21 to move back and forth.

Here, as shown in Figure 4, the mounting groove 41 is formed in the middle portion of the rotating portion 28, through the mounting groove 41, for example, by mounting a water pump, the excavation of the rod By applying water pressure in the direction, it can be configured to remove rock debris and the like generated during excavation.

Therefore, through the configuration as shown in Figs. 2 to 4, through the mounting portion 26, after installing the advanced horizontal drilling device 20 in the tunnel construction device, such as TBM, the rod is mounted in the perforated portion 22 In addition, when the perforated part is advanced through the chain belt 25 while driving the driving motor to rotate the rod, the rod is advanced through the first guide 23 and the second guide 24 to be excavated.

At this time, by applying a water pressure through the water pump as described above can remove the rock debris generated during the excavation, and, although not shown, by mounting a sample collector for drilling core sampling at the end of the rod, After the drilling core is taken out, the sample core can be easily recovered by reversing the punching section 22.

Here, the advanced horizontal drilling apparatus 20 of the present embodiment shown in Figure 2 shows an example configured to be mounted on the recycled TBM equipment of Φ3.5m and Φ7.0m class that is currently used in Korea a lot, the present invention is such It should be noted that the present invention is not limited only to the case, and can be applied to other forms in addition to the forms shown in the present embodiment.

More specifically, domestically operated recycled TBM equipment differs in working space according to size and specifications. In general, various devices such as chambers, pressure cells, conveyors, and cylinders are located at the rear of the cutter head. Restricted

Therefore, the advanced horizontal drilling apparatus 20 according to the present invention is appropriately designed in consideration of the conditions such as the drilling space and drilling efficiency of the working space and the drilling apparatus itself in such TBM equipment.

That is, the advanced horizontal drilling apparatus 20 for anterior geological prediction according to an embodiment of the present invention is made of a top head method capable of impact and rotational drilling by mounting a drifter as described above, thereby, The core recovery and non-core operation is possible at the same time, and it is configured to increase the drilling rate and core recovery rate for the composite ground.

In addition, the advanced horizontal drilling device 20 of the present embodiment can be actively operated through the probe drilling injection hole in the TBM equipment, at this time, it is possible to recover the drilling core of various sizes by changing the drilling bore diameter, efficiency In order to maximize the control of the device by wired or wireless remote control method.

In addition, the advanced horizontal drilling apparatus 20 according to the present embodiment may be configured to further include a drilling data calculation unit for measuring the various parameters during the drilling operation to calculate the drilling data.

Here, when it is impossible to recover the drilling core due to faults, crushing zones, cavities, etc. according to the ground conditions, the front and side images of the borehole are simultaneously recorded through a CCD camera, and a real time image of the geological state around the borehole is configured. A borehole camera system can be inserted in place of the bore core harvester to determine the geological conditions around the borehole.

That is, referring to FIG. 5, FIG. 5 is inserted in place of a drilling core harvester when recovery of the drilling core is impossible as described above, so that the lipid prediction may be performed through a real-time image of the lipid state around the borehole. It is a figure which shows roughly the whole structure of the borehole camera system 50. FIG.

In more detail, as shown in FIG. 5, the borehole camera system 50 according to the embodiment of the present invention includes a camera body 51 having a cylindrical shape and a concave cutting groove formed in a middle portion thereof, and the camera. The front lighting unit 53 including a front camera 52 and a plurality of LEDs provided on the front of the main body 51, the side camera 54 and at least one LED installed on the side of the camera main body 51 It is configured to include a side lighting unit 55 and a cable connecting portion 56 is installed on the rear of the camera body 51.

In addition, the borehole camera system 50 is configured to further include a control unit for controlling the shooting of the camera from the outside, and a monitor unit 60 having a monitor and a storage device for displaying and storing the captured image. .

That is, referring to FIG. 6, FIG. 6 schematically illustrates an overall configuration of a monitor 60 for controlling the operation of the camera main body shown in FIG. 5 and displaying a captured image.

More specifically, the monitor unit 60, as shown in Figure 6a, is configured in the form of a hard case to be easy to carry and move and at the same time protect the inside from an external shock, such a case 61 As shown in Fig. 6B, a monitor 62 on which an image captured by each camera is displayed, and a control panel 63 for controlling the operation of each camera and the monitor are provided.

Here, the camera body 51 and the monitor unit 60 may be configured to be connected by wire or wirelessly using a cable through the cable connection unit 56, and may be configured as necessary. Accordingly, the electronic device may further include a storage unit for storing the captured image.

In addition, the borehole camera system 50 may be configured such that the monitor unit 60 includes two monitors that respectively display an image of the front camera 52 and an image of the side camera 54. Alternatively, it is configured to display only one of the image of the front camera 52 and the image of the side camera 54 with only one monitor, or to switch and display a method of simultaneously displaying both images on one screen as necessary. Can be.

Furthermore, although not shown, the borehole camera system 50 further includes a meter counter and a temperature sensor for detecting a groundwater characteristic by detecting a temperature difference due to groundwater movement in a fault or crushing zone, each sensor in the image. May be configured to be displayed together.

Therefore, through the configuration as described above, the front camera 52 and the front lighting unit 53 is photographed in front of the image at the same time, the side camera 54 and the side lighting unit 55 is installed on the side Taking an image, the monitor unit 60 can check each image from the outside.

In addition, referring to Figure 7, Figure 7a is a view of the air coupling 70 used for the non-core operation of the advanced borehole horizontal drilling device 20 for predicting forward lipid according to an embodiment of the present invention as described above It is a figure which shows roughly a structure, and FIG. 7B is its sectional drawing.

More specifically, the air coupling 70 is formed as a hollow cylinder as a whole and is a device for injecting compressed air through the compressed air inlet 71 to perform a non-coring operation, as shown in FIG. Two bearings 72 are respectively located inside the both ends and are fixed by the bearing fixture 73, air is supplied to the bit core portion by the inner casing 74, and the non-coring operation is performed by the drilling bit of the drilling portion. It is configured to proceed.

Here, the inner casing 74, as shown in the cross-sectional view of Figure 7b, is composed of a form in which two semi-circles facing the compressed air inlet 71, the interval is the size and the compressed air inlet 71 Configured to be the same.

In addition, the female screw portion 75 and the male screw portion 76 are formed at both ends of the air coupling 70, and the female screw portion 75 is connected to the punching portion 22, and the male screw portion 76 has a rod and The casing is connected and configured to proceed with the excavation work after the maximum air is injected by rotating at a low speed during drilling.

As described above, the advanced borehole horizontal drilling apparatus 20 for anterior lipid prediction according to the embodiment of the present invention can be implemented, and further, the anterior lipid prediction according to the embodiment of the present invention configured as described above By installing the advanced horizontal drilling device 20 for a tunnel construction device, such as TBM equipment, it is possible to implement a tunnel construction device that can predict the ground in front of the membrane and a tunnel construction method using the same.

In addition, the database for the drilling parameters including the rotational pressure, penetration rate, torque, thrust, depth, etc. using the TBM-mounted soil evaluation system using the advanced borehole for predicting forward lipid according to the embodiment of the present invention as described above By constructing and calculating the puncture index based on such data, it can be utilized as a system for the ground evaluation by the puncture index.

More specifically, referring to FIG. 8, FIG. 8 is a construction for constructing a tunnel using a tunnel factory equipped with a TBM-mounted soil evaluation system using advanced boreholes for predicting forward lipids according to the present invention as described above. A flowchart schematically illustrating the overall configuration of the method.

That is, as shown in Figure 7, the tunnel construction method using a tunnel factory with a TBM-mounted ground evaluation system using the advanced borehole according to the present invention, first, as described above, using the advanced borehole according to the present invention Implementing an advanced horizontal drilling device for installing the TBM-mounted ground evaluation system (step S81); mounting the advanced horizontal drilling device implemented in the step to a tunnel construction device such as TBM (step S82); In the step of predicting the geology of the front through the advanced horizontal drilling device using the tunnel factory equipped with the advanced horizontal drilling device (step S83) and the tunnel according to the results of the lipid predicted through the advanced horizontal drilling device in the step And a step of constructing the tunnel by excavating using the factory setting (step S84).

Therefore, as described above, it is possible to implement the TBM-mounted ground evaluation system using the advanced borehole for predicting forward geology according to the present invention, the tunnel construction device and the tunnel construction method using the same.

In addition, according to the present invention by implementing the TBM-mounted ground evaluation system using the advanced borehole for predicting forward geology according to the present invention, the tunnel construction apparatus and the tunnel construction method using the same, as described above, Advanced borehole ground evaluation system for advanced geological prediction, including advanced drilling equipment for performing geological analysis, and borehole imaging equipment for imaging the inside of the borehole to enable geological analysis in a non-core manner even when recovery of the core is impossible. By attaching to the TBM equipment, it is possible not only to predict the ground condition in the front by taking a sample of the front ground at the time of tunnel excavation, but also to predict the ground at the front when the drilling core cannot be recovered.

In addition, according to the present invention, as described above, there is provided with a TBM-mounted ground evaluation system using advanced boreholes for the prediction of forward lipids that can be predicted by both the method using the drilling core and the non-core method without using the drilling core By providing a tunnel construction device and a tunnel construction method using the same, it is difficult to visually check the excavation cross section, and it is not easy to cope with sudden ground changes or groundwater. It is possible to solve the problems of the conventional TBM equipment and the tunnel construction method using the same that caused the economic loss.

As mentioned above, although the tunnel construction apparatus provided with the TBM mounting ground evaluation system using the advanced borehole according to this invention through the Example of this invention was described in detail, the tunnel construction method using the same, The present invention said The present invention is not limited only to the contents described in one embodiment, and thus, the present invention can be modified, changed, combined, and modified according to design needs and various other factors by those skilled in the art. It is natural that replacement is possible.

10. Soil Assessment System 11. Advanced Drilling Department
12. Borehole Imaging Unit 13. Mounting Unit
14. Geological Analysis Department 15. Control Unit
20. Advanced Horizontal Drilling Rigs 21. Mainframe
22. Perforation 23. First guide
24. Second guide 25. Chain belts
26. Mounting part 27. Rod mounting part
28. Rotating part 29. Coupling part
41. Mounting groove 50. Borehole camera system
51. Camera Body 52. Front Camera
53. Front light 54. Side camera
55. Side light 56. Cable connection
60. Monitor 61. Case
62. Monitor 63. Control panel
70. Air coupling 71. Compressed air inlet
72. Bearing 73. Bearing Fixture
74. Inner casing 75. Female thread
76. Male thread

Claims (22)

delete delete delete delete delete Both the drilling core method for recovering the drilling core and performing the lipid analysis to predict the lipid ahead of the drilling direction installed in the tunnel construction device including the tunnel boring machine, and the non-core lipid analysis without the recovery core. An advanced horizontal drilling apparatus for predicting anterior lipids configured to be possible,
A main frame forming a main body of the advanced horizontal drilling device;
A perforation part installed to be movable back and forth on the mainframe and mounted with a rod for drilling a borehole;
A first guide installed at a front end of the main frame to guide the rod;
A second guide installed at a front end of the first guide to support the rod;
A chain belt for moving the perforation part back and forth on the mainframe;
A mounting part for supporting the advanced horizontal drilling device and mounting the tunnel drilling device;
A drive motor for supplying power to drive the chain belt to move the perforation part back and forth on the main frame;
A control unit for controlling the overall operation of the advanced horizontal drilling device;
A sampler mounted to an end of the rod for collecting the drilling core; And
It is configured to include a borehole camera that provides a real-time image of the front and side of the borehole in order to determine the geological conditions around the borehole when the recovery of the borehole core is impossible,
After installing the advanced horizontal drilling device in the tunnel construction device through the mounting portion, the rod is mounted to the drilling portion, the driving motor is driven to rotate the rod while advancing the drilling portion through the chain belt. When the rod is rotated through the first guide and the second guide to move forward to excavate the borehole, and after drilling the borehole to extract the drilling core through the sampler to perform a lipid analysis,
When the recovery of the core is impossible, advanced horizontal for anterior lipid prediction, characterized in that the insertion of the borehole camera in place of the sampler to take a real-time image of the front and side of the borehole to perform a lipid analysis Drilling rig.
The method according to claim 6,
The advanced horizontal drilling device,
An advanced horizontal drilling apparatus for predicting forward geology, characterized in that it further comprises a water pump for applying water pressure in the drilling direction during drilling.
8. The method of claim 7,
Wherein the perforations
A rod mounting unit on which the rod is mounted;
A rotating part provided with a rotating shaft for rotating the rod;
A coupling part for slidably coupling the perforation part to the main frame to be movable back and forth through the chain belt; And
It is configured to include a mounting groove formed in the middle portion of the rotating part,
Advanced horizontal drilling device for forward geological prediction, characterized in that for mounting the water pump through the mounting groove to apply water pressure in the excavation direction of the rod.
The method of claim 8,
The advanced horizontal drilling device,
An advanced horizontal drilling apparatus for predicting the front lipid, characterized in that configured to change the bore diameter to enable the recovery of the drilling core.
The method of claim 9,
The advanced horizontal drilling device,
An advanced horizontal drilling apparatus for anterior geological prediction, characterized in that it further comprises a drilling data calculation unit for measuring the various parameters during the drilling operation to calculate the drilling data.
The method of claim 10,
The borehole camera,
A camera body formed in a cylindrical shape and having a recessed cutting groove formed in a middle portion thereof;
A front lighting unit including a front camera and a plurality of LEDs installed on the front of the camera body;
A side lighting unit including a side camera installed on the side of the camera body and at least one LED;
Advanced horizontal drilling device for the front geological prediction, characterized in that it comprises a cable connection is installed on the rear of the camera body.
12. The method of claim 11,
The borehole camera,
A controller for controlling shooting of the borehole camera from the outside; And
And a monitor unit having a monitor and a storage device for displaying and storing an image captured by the borehole camera.
13. The method of claim 12,
The monitor unit,
A case configured in the form of a hard case to be easy to carry and move and to protect the inside from an external shock;
A monitor installed in the case and displaying an image captured by the borehole camera; And
And a control panel installed in the case and configured to control the operation of the borehole camera and the monitor.
The method of claim 13,
The monitor unit,
An advanced horizontal drilling apparatus for forward geological prediction, further comprising a storage unit installed in the case to store an image photographed by the borehole camera.
The method of claim 14,
The camera body and the monitor unit, the horizontal horizontal drilling apparatus for the front geological prediction, characterized in that configured to be connected by wire or wirelessly via the cable connection unit.
16. The method of claim 15,
The monitor unit,
It is configured to have two monitors for displaying the image of the front camera and the image of the side camera, respectively,
An advanced horizontal drilling apparatus for anterior geological prediction, characterized in that it is configured to display only one monitor by switching the display method of one or two images of the image of the front camera and the image of the side camera at the same time.
17. The method of claim 16,
The advanced horizontal drilling device,
It further includes a meter counter and temperature sensor for detecting the groundwater characteristics by detecting the temperature difference caused by the groundwater movement in the fault or crushing zone,
Advanced horizontal drilling device for anterior geological prediction, characterized in that it is configured to display together the measurements of each sensor in the captured image.
18. The method of claim 17,
The advanced horizontal drilling device,
By constructing a database for the drilling parameters by measuring the drilling parameters including the rotational pressure, penetration speed, torque, thrust, depth of the rod through each sensor,
Calculating a perforation index on the basis of the database, the advanced horizontal drilling apparatus for predicting the front geology, characterized in that configured to perform the ground evaluation by the perforation index.
19. The method of claim 18,
The advanced horizontal drilling device,
An advanced horizontal drilling apparatus for anterior geological prediction, characterized in that it further comprises an air coupling for forming a hollow cylinder and injecting compressed air to perform a non-coring operation.
20. The method of claim 19,
The air coupling,
A compressed air inlet for injecting compressed air;
Bearings respectively located inside both ends;
Bearing fixtures for securing each of the bearings;
An inner casing formed with two semicircles facing each other at the same interval as the size of the compressed air inlet with respect to the compressed air inlet; And
Both ends are configured to include a female screw portion and a male screw portion respectively formed,
The female screw portion is connected to the perforated portion, and the advanced horizontal drilling device for forward geological prediction, characterized in that the male screw portion is configured to be connected to the rod and the casing.
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