All Issue

2024 Vol.34, Issue 1

Technical Note

Evaluation of Applicability for 3D Scanning of Abandoned or Flooded Mine Sites Using Unmanned Mobility

무인 이동체를 이용한 폐광산 갱도 및 수몰 갱도의 3차원 형상화 위한 적용성 평가

Soolo Kim1
,
Gwan-in Bak1
,
Sang-Wook Kim2*
,
Seung-han Baek1
김 수로1
,
박 관인1
,
김 상욱2*
,
백 승한1
1Deputy Director, Korea Mine Rehabilitation and Mineral Resources Corp.
2Principal Engineer, Isung Co. Ltd.
1한국광해광업공단 수석연구원
2이성주식회사 차장
*Corresponding Author
29 February 2024. pp. 1-14
PDF XML Citation
Abstract

An image-reconstruction technology, involving the deployment of an unmanned mobility equipped with high-speed LiDAR (Light Detection And Ranging) has been proposed to reconstruct the shape of abandoned mine. Unmanned mobility operation is remarkably useful in abandoned mines fraught with operational difficulties including, but not limited to, obstacles, sludge, underwater and narrow tunnel with the diameter of 1.5 m or more. For cases of real abandoned mines, quadruped robots, quadcopter drones and underwater drones are respectively deployed on land, air, and water-filled sites. In addition to the advantage of scanning the abandoned mines with 2D solid-state lidar sensors, rotation of radiation at an inclination angle offers an increased efficiency for simultaneous reconstruction of mineshaft shapes and detecting obstacles. Sensor and robot posture were used for computing rotation matrices that helped compute geographical coordinates of the solid-state lidar data. Next, the quadruped robot scanned the actual site to reconstruct tunnel shape. Lastly, the optimal elements necessary to increase utility in actual fields were found and proposed.

Keywords
Lidar
3D scanning system
Safety inspection
Unmanned mobility
Drone

폐광산의 갱도 입구를 통해 고속 라이다(Light Detection And Ranging, LiDAR) 장비가 탑재된 무인 이동체를 투입하여 폐광의 갱도를 형상화하기 위한 기술이 제안되었다. 직경이 1.5 m 이상인 좁은 갱도에 바닥이 슬러지 형태로 미끄럽고 장애물이 있는 환경에서 무인 이동체를 운영할 때 고려할 사항을 검토하였다. 육상환경 이동을 위해 4족 보행 로봇을 활용하였으며 항공 환경 이동을 위해 쿼드콥터 드론이 활용되었다. 수중환경의 갱도에 투입하기 위해서 수중 드론이 사용되었다. 무인 이동체를 실제 광산 현장에 투입하여 폐광 현장용 이동체가 고려해야 할 변수들을 도출하였다. 폐광산 갱도 형상화용 센서로서 2차원 영상 기반의 solid-state 라이다가 사용되었다. 방사형으로 측정되는 라이다의 특성을 고려하여 고정 경사각을 두어 회전시켜 운영하여 갱도 형상화를 위한 효율성을 높이고 동시에 장애물 감지도 같이 수행할 수 있도록 제안하였다. Solid-state 라이다를 이용하여 측정데이터로부터 센서의 자세와 로봇의 자세를 반영하여 현실 좌표계 데이터로 변환하기 위한 계산기법이 도출되었다. 라이다 센서와 무인 비행체가 결합하여 실제 현장에 투입하여 갱도 형상을 추출하였다. 마지막으로 실제 현장에서 효용성을 높이기 위한 요소를 도출하였다.

키워드
라이다
3차원 스캐닝 시스템
안전진단
무인이동체
드론
References
1
Durrant-Whyte, H. and Bailey, T., 2006, Simultaneous localization and mapping: part I, IEEE Robotics & Automation magazine, 13(2), 99-110. 10.1109/MRA.2006.1638022
2
Fekete, S., Diederichs, M., and Lato, M. 2010, Geotechnical and operational applications for 3-dimensional laser scanning in drill and blast tunnels, Tunnelling and Underground Space Technology, 25(5), 614-628. 10.1016/j.tust.2010.04.008
3
Garcia-Gomez, P., Royo, S., Rodrigo, N., and Casas, J.R., 2020, Geometric model and calibration method for solid-state lidar, Senosrs, 20(10), 2898. 10.3390/s2010289832443805PMC7287784
4
Ghosh, D., Samanta, B., and Chakravarty, D., 2017, Multi sensor data fusion for 6D pose estimation and 3D underground mine mapping using autonomous mobile robot, International Journal of Image and Data Fusion, 8(2), 173-187. 10.1080/19479832.2016.1226966
5
Hong, G.W., Kim, S.M., and Park, J.J., 2022, A study on the calculation of cavity filling amount using ground penetrating radar and cavity shaping equipment, J. Soc. Disaster Information, 18(2), 261-268.
6
Jeon, S.W. and Jeon, B.K., 2014, Review on the prevention and reclamation of mining induced subsidence in abandoned mine areas in the Republic of Korea, J. Korean Soc. Miner. Energy Resour. Eng., 51(1), 141-150. 10.12972/ksmer.2014.51.1.141
7
Kim, H.M. and Choi, Y.S., 2019, Review of Autonomous Driving Technology Utilized in Underground Mines, J. Korean Soc. Miner. Energy Resour. Eng., 56(5), 480-489. 10.32390/ksmer.2019.56.5.480
8
Kim, S.L., Bak, G.I., and Baek, S.H., 2021, Application of underground caivty 3d digitization and figuration technology to underground safety industry, J. Korean Soc. Miner. Energy Resour. Eng., 58(4), 364-370. 10.32390/ksmer.2021.58.4.364
9
Kim, S.L., Choi, J.S., Yoon, H.G., and Kim, S.W., 2022, Fabrication of three-dimensional scanning system for inspection of mineshaft using multichannel lidar, Tunnel and Underground Space 32(6), 451-463.
10
Kim, S.L., Pak, J.H., Lee, J.S., Yang, I.J., and Kim, S.W., 2020a, Towing-type high-speed three-dimensional shaping and method for sinkholes and underground cavities, Korea Patent, 10-2205218.
11
Kim, S.L., Yoon, H.G., and Kim, S.W., 2020b, Fabrication of three-dimensional scanning system for inspection of massive sinkhole disaster sites, J. of Korea Robotics Society, 15(4), 341-349. 10.7746/jkros.2020.15.4.341
12
Kim, S.W. and Kim, S.Y., 2010, Analysis of cross-borehole pulse radar signatures measured at various tunnel angle, Exploration Geophysics, 41(1), 96-101. 10.1071/EG09048
13
Neumann, T., Ferrein, A., Kallweit, S., and Scholl, I., 2014, Towards a mobile mapping robot for underground mines, Proceedings of the 2014 PRASA, RobMech and AfLaT International Joint Symposium, 27-32.
14
Singh, S.K., Banerjee, B.P., and Raval, S., 2023, A review of laser scanning for geological and geotechnical applications in underground mining, International Journal of Mining Science and Technology, 33(2), 133-154. 10.1016/j.ijmst.2022.09.022
15
Singh, S.K., Raval, S., and Banerjee, B., 2021, A robust approach to identify roof bolts in 3D point cloud data captured from a mobile laser scanner, International Journal of Mining Science and Technology, 31(2), 303-312. 10.1016/j.ijmst.2021.01.001
16
Tatsch, C., Bredu, J.A., Covell, D., Tulu, I.B., and Gu, Y. 2023, Rhino: An Autonomous Robot for Mapping Underground Mine Environments, 2023 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM), 1166-1173. 10.1109/AIM46323.2023.10196202
17
Zlot, R., and Bosse, M. 2013, Efficient large-scale 3D mobile mapping and surface reconstruction of an underground mine, Field and Service Robotics, 8th International Conference, 479-493. 10.1007/978-3-642-40686-7_32
Information
  • Publisher :Korean Society for Rock Mechanics and Rock Engineering
  • Publisher(Ko) :한국암반공학회
  • Journal Title :Tunnel and Underground Space
  • Journal Title(Ko) :터널과 지하공간
  • Volume : 34
  • No :1
  • Pages :1-14
  • Received Date : 2023-12-05
  • Revised Date : 2024-01-03
  • Accepted Date : 2024-01-03
  • DOI :https://doi.org/10.7474/TUS.2024.34.1.001
Journal Informaiton Tunnel and Underground Space Tunnel and Underground Space
Online Submission
Archives
: Vol.27, 2017 ~
  • NRF
  • KOFST
  • KISTI Current Status
  • KISTI Cited-by
  • crosscheck
  • orcid
  • open access
  • ccl
Journal Informaiton Journal Informaiton - close