Terrestrial laser scanning in the construction of a numerical model geometry related to underground post-mining facility

[1] Autodesk AutoCAD 2024 - computer-assisted design software (CAD) In-text reference: (AutoCad, 2023) Autodesk AutoCAD 2024 - computer-assisted design software (CAD) In-text reference: (AutoCad, 2023) Search in Google Scholar

[2] Bock S. (2015). New open-source ANSYS-SolidWorks-FLAC3D geometry conversion programs. Journal of Sustainable Mining 14(3), pp.124–132. https://doi.org/10.1016/j.jsm.2015.11.002. In-text reference: (Bock, 2015) BockS. 2015 New open-source ANSYS-SolidWorks-FLAC3D geometry conversion programs Journal of Sustainable Mining 14 3 124 132 https://doi.org/10.1016/j.jsm.2015.11.002. In-text reference: (Bock, 2015) Search in Google Scholar

[3] CloudCompare - Open Source project. 3D point cloud and mesh processing software. In-text reference: (CloudCompare, 2023) CloudCompare - Open Source project 3D point cloud and mesh processing software In-text reference: (CloudCompare, 2023) Search in Google Scholar

[4] D’Obryn, K., & Hydzik-Wiśniewska, J., (2013). Selected aspects of numerical modelling of the salt rock mass: the case of the „Wieliczka” salt mine. Archives of Mining Sciences, Vol. 58 (2013), No 1, p. 73–88. DOI:10.2478/AMSC-2013-0005 In-text reference: (D’Obryn & Hydzik-Wiśniewska, 2013) D’ObrynK. Hydzik-WiśniewskaJ. 2013 Selected aspects of numerical modelling of the salt rock mass: the case of the „Wieliczka” salt mine Archives of Mining Sciences 58 2013 1 73 88 10.2478/AMSC-2013-0005 In-text reference: (D’Obryn & Hydzik-Wiśniewska, 2013) Open DOISearch in Google Scholar

[5] D’Obryn, K., & Hydzik-Wiśniewska, J., (2017). Assessment of rock mass stability in the historic area of levels IV–V of the „Wieliczka” salt mine of the „Wieliczka” salt mine. Archives of Mining Sciences, Vol. 62, No 1, p. 189–202. DOI 10.1515/amsc-2017-0014 In-text reference: (D’Obryn & Hydzik-Wiśniewska, 2013) D’ObrynK. Hydzik-WiśniewskaJ. 2017 Assessment of rock mass stability in the historic area of levels IV–V of the „Wieliczka” salt mine of the „Wieliczka” salt mine Archives of Mining Sciences 62 1 189 202 10.1515/amsc-2017-0014 In-text reference: (D’Obryn & Hydzik-Wiśniewska, 2013) Open DOISearch in Google Scholar

[6] Emad, M.Z., & Mitri, H., & Kelly, C. (2014). Effect of blast-induced vibrations on fill failure in vertical block mining with delayed backfill. Canadian Geotechnical Journal 51(9). https://doi.org/10.1139/cgj-2013-0305. In-text reference: (Emad et al 2014) EmadM.Z. MitriH. KellyC. 2014 Effect of blast-induced vibrations on fill failure in vertical block mining with delayed backfill Canadian Geotechnical Journal 51 9 https://doi.org/10.1139/cgj-2013-0305. In-text reference: (Emad et al 2014) Search in Google Scholar

[7] Fekete, S., & Diederichs, M., & Lato, M. (2010). Geotechnical and operational applications for 3-dimensional laser scanning in drill and blast tunnels. Tunneling and Underground Space Technology 25(5), pp.614–628. https://doi.org/10.1016/j.tust.2010.04.008. In-text reference: (Fekete et al., 2010) FeketeS. DiederichsM. LatoM. 2010 Geotechnical and operational applications for 3-dimensional laser scanning in drill and blast tunnels Tunneling and Underground Space Technology 25 5 614 628 https://doi.org/10.1016/j.tust.2010.04.008. In-text reference: (Fekete et al., 2010) Search in Google Scholar

[8] FLAC (FLAC2D/FLAC3D) — Itasca Software 9.0 documentation (itascacg.com). Itasca Consulting Group In-text reference: (Itasca, 2023) FLAC (FLAC2D/FLAC3D) — Itasca Software 9.0 documentation (itascacg.com) Itasca Consulting Group In-text reference: (Itasca, 2023) Search in Google Scholar

[9] Hassan, M.U., & Akcanete-Gungor, A., & Meral, C. (2017). Investigation of terrestrial laser scanning reflectance intensity and RGB distributions to assist construction material identification. LC3 Proceedings of the Joint Conference on Computing in Construction, 04-07 Heraklion, Greece July, pp. 507–515. https://doi.org/10.24928/JC3-2017/0312. In-text reference: (Hassan et al., 2017) HassanM.U. Akcanete-GungorA. MeralC. 2017 Investigation of terrestrial laser scanning reflectance intensity and RGB distributions to assist construction material identification LC3 Proceedings of the Joint Conference on Computing in Construction 04-07 Heraklion, Greece July 507 515 https://doi.org/10.24928/JC3-2017/0312. In-text reference: (Hassan et al., 2017) Search in Google Scholar

[10] Huang, Z.P., & Broch, E., & Lu, M. (2002). Cavern roof stability — mechanism of arching and stabilization by rockbolting. Tunneling and Underground Space Technology 17(3), pp. 249–261. https://doi.org/10.1016/S0886-7798(02)00010-X. In-text reference: (Huang et al. 2002) HuangZ.P. BrochE. LuM. 2002 Cavern roof stability — mechanism of arching and stabilization by rockbolting Tunneling and Underground Space Technology 17 3 249 261 https://doi.org/10.1016/S0886-7798(02)00010-X. In-text reference: (Huang et al. 2002) Search in Google Scholar

[11] Huang, X., & Ruan, H., & Shi, C., & Kong, Y. (2021). Numerical Simulation of Stress Arching Effect in Horizontally Layered Jointed Rock Mass. Symmetry, 13, 1138. https://doi.org/10.3390/sym13071138 In-text reference: (Huang et al. 2021) HuangX. RuanH. ShiC. KongY. 2021 Numerical Simulation of Stress Arching Effect in Horizontally Layered Jointed Rock Mass Symmetry 13 1138 https://doi.org/10.3390/sym13071138 In-text reference: (Huang et al. 2021) Search in Google Scholar

[12] Huber, D.F., & Vandapel, N. (2006). Automatic 3D Underground Mine Mapping. The International Journal of Robotics Research 25(1), pp. 7–17, 2006. https://doi.org/10.1007/10991459_48. In-text reference: (Huber & Vandapel, 2006) HuberD.F. VandapelN. 2006 Automatic 3D Underground Mine Mapping The International Journal of Robotics Research 25 1 7 17 2006 https://doi.org/10.1007/10991459_48. In-text reference: (Huber & Vandapel, 2006) Search in Google Scholar

[13] Humair, F., & Abellan A., & Carrea, D., & Matasci, B., & Luc, J., & Jaboyedoff E., & Jaboyedoff M. (2015) Geological layers detection and characterisation using high resolution 3D point clouds: example of a box-fold in the Swiss Jura Mountains. European Journal of Remote Sensing, 48(1), pp.541–568. https://doi.org/10.5721/EuJRS20154831. In-text reference: (Humair et al., 2015) HumairF. AbellanA. CarreaD. MatasciB. LucJ. JaboyedoffE. JaboyedoffM. 2015 Geological layers detection and characterisation using high resolution 3D point clouds: example of a box-fold in the Swiss Jura Mountains European Journal of Remote Sensing 48 1 541 568 https://doi.org/10.5721/EuJRS20154831. In-text reference: (Humair et al., 2015) Search in Google Scholar

[14] Janus, J., & Ostrogórski, P. (2022). Underground Mine Tunnel Modelling Using Laser Scan Data in Relation to Manual Geometry Measurements. Energies 15(7), 2537. https://doi.org/10.3390/en15072537. In-text reference: (Janus & Ostrogórski, 2022) JanusJ. OstrogórskiP. 2022 Underground Mine Tunnel Modelling Using Laser Scan Data in Relation to Manual Geometry Measurements Energies 15 7 2537 https://doi.org/10.3390/en15072537. In-text reference: (Janus & Ostrogórski, 2022) Search in Google Scholar

[15] Kajzar, V., & Kukutsch, R., & Heroldová, N. (2015). Verifying the possibilities of using a 3D laser scanner in the mining underground. Acta Geodynamica et Geomaterialia 12(1), 177. https://doi.org/10.13168/AGG.2015.0004. In-text reference: (Kajzar et al., 2015) KajzarV. KukutschR. HeroldováN. 2015 Verifying the possibilities of using a 3D laser scanner in the mining underground Acta Geodynamica et Geomaterialia 12 1 177 https://doi.org/10.13168/AGG.2015.0004. In-text reference: (Kajzar et al., 2015) Search in Google Scholar

[16] Kobylańska, M. (2012). Conditions for implementation of the programme of post-mining relics’ management for geotourism on example of the project „Reclamation of territories degraded by mining activities in the area of the mirsk commune and establishing the tourist route – by the traces of the former ore mining”. International Twin Conference GEOTOUR & IRSE 2012 Geoparks, Geoheritage and Geoconservation IRSE: History of Central European Mining, Salgótarján, Hungary 04–06 October. https://doi.org/10.13140/RG.2.1.3702.4803. In-text reference: (Kobylańska, 2012) KobylańskaM. 2012 Conditions for implementation of the programme of post-mining relics’ management for geotourism on example of the project „Reclamation of territories degraded by mining activities in the area of the mirsk commune and establishing the tourist route – by the traces of the former ore mining” International Twin Conference GEOTOUR & IRSE 2012 Geoparks, Geoheritage and Geoconservation IRSE: History of Central European Mining Salgótarján, Hungary 04–06 October https://doi.org/10.13140/RG.2.1.3702.4803. In-text reference: (Kobylańska, 2012) Search in Google Scholar

[17] Madziarz, M. (2012). Historical ore mining sites in Lower Silesia (Poland) as geotourism and industrial tourism attraction. International Twin Conference GEOTOUR & IRSE 2012 Geoparks, Geoheritage and Geoconservation IRSE: History of Central European Mining, Salgótarján, Hungary 04–06 October. https://doi.org/10.13140/RG.2.1.3702.4803. In-text reference: (Madziarz, 2012) MadziarzM. 2012 Historical ore mining sites in Lower Silesia (Poland) as geotourism and industrial tourism attraction International Twin Conference GEOTOUR & IRSE 2012 Geoparks, Geoheritage and Geoconservation IRSE: History of Central European Mining Salgótarján, Hungary 04–06 October https://doi.org/10.13140/RG.2.1.3702.4803. In-text reference: (Madziarz, 2012) Search in Google Scholar

[18] Madziarz, M., Kobylańska, M. (2014). Geopark „Along the footprints of old ore mining” as an in-novative project and new geotourism attraction in Poland. 14th International Multidisciplinary Scientific Geo-Conference and Expo 2014 Albena, Bulgaria 17–26 June 2014,1(1). In-text reference: (Madziarz & Kobylańska, 2014) MadziarzM. KobylańskaM. 2014 Geopark „Along the footprints of old ore mining” as an in-novative project and new geotourism attraction in Poland 14th International Multidisciplinary Scientific Geo-Conference and Expo 2014 Albena, Bulgaria 17–26 June 2014 1 1 In-text reference: (Madziarz & Kobylańska, 2014) Search in Google Scholar

[19] Mao, J.Z., & Zuo, G., (2017). Modeling method of FLAC3D based on RHINO-KUBRIX and deformation analysis of tunnel lining structure. Advances in Engineering Research, 112, pp. 520–528. http://doi.org/10.2991/icreet-16.2017.87. In-text reference: (Mao & Zuo, 2017) MaoJ.Z. ZuoG. 2017 Modeling method of FLAC3D based on RHINO-KUBRIX and deformation analysis of tunnel lining structure Advances in Engineering Research 112 520 528 http://doi.org/10.2991/icreet-16.2017.87. In-text reference: (Mao & Zuo, 2017) Search in Google Scholar

[20] Monsalve, J., & Baggett, J., & Bishop, R., & Ripepi, N. (2018). Application of laser scanning for rock mass characterization and discrete fracture network generation in an underground limestone mine. International Journal of Mining Science and Technology, 29(1), pp. 131–137. https://doi.org/10.1016/j.ijmst.2018.11.009. In-text reference: (Monsalve et al., 2018) MonsalveJ. BaggettJ. BishopR. RipepiN. 2018 Application of laser scanning for rock mass characterization and discrete fracture network generation in an underground limestone mine International Journal of Mining Science and Technology 29 1 131 137 https://doi.org/10.1016/j.ijmst.2018.11.009. In-text reference: (Monsalve et al., 2018) Search in Google Scholar

[21] Rozmus, M., & Tokarczyk, J., & Michalak, D., & Dudek, M., & Szewerda, K., & Rotkegel, M., & Lamot, A., & Rošer, J. (2021). Application of 3D Scanning, Computer Simulations and Virtual Reality in the Redesigning Process of Selected Areas of Underground Transportation Routes in Coal Mining Industry. Energies 14(9), 2589. https://doi.org/10.3390/en14092589. In-text reference: (Rozmus et al., 2021) RozmusM. TokarczykJ. MichalakD. DudekM. SzewerdaK. RotkegelM. LamotA. RošerJ. 2021 Application of 3D Scanning, Computer Simulations and Virtual Reality in the Redesigning Process of Selected Areas of Underground Transportation Routes in Coal Mining Industry Energies 14 9 2589 https://doi.org/10.3390/en14092589. In-text reference: (Rozmus et al., 2021) Search in Google Scholar

[22] Trimble Inc.: Laser scanner TX8 technical data sheet In-text reference: (Trimble, 2016) Trimble Inc.: Laser scanner TX8 technical data sheet In-text reference: (Trimble, 2016) Search in Google Scholar

[23] Trimble RealWorks - Trimble Geospatial. Point cloud processing and analysis software for 3D laser scanning professionals. In-text reference: (TRW, 2023) Trimble RealWorks - Trimble Geospatial Point cloud processing and analysis software for 3D laser scanning professionals In-text reference: (TRW, 2023) Search in Google Scholar

[24] Ulewicz M., & Pawłowicz, J. 2022. Reflection intensity of terrestrial laser scanning dependence on the physical properties of building materials and scanning conditions. Materiały Budowlane, 11. https://doi.org/10.15199/33.2022.11.17. In-text reference: (Ulewicz & Pawłowicz, 2022) UlewiczM. PawłowiczJ. 2022 Reflection intensity of terrestrial laser scanning dependence on the physical properties of building materials and scanning conditions Materiały Budowlane 11 https://doi.org/10.15199/33.2022.11.17. In-text reference: (Ulewicz & Pawłowicz, 2022) Search in Google Scholar

[25] Wang, S., & Zhang, Q., (2010). A Coupling Modeling Method with MIDAS/GTS-FLAC 3D and Its Application. Journal of Civil, Architectural & Environmental Engineering, 32(1), pp. 12–17. In-text reference: (Wang & Zhang, 2010) WangS. ZhangQ. 2010 A Coupling Modeling Method with MIDAS/GTS-FLAC 3D and Its Application Journal of Civil, Architectural & Environmental Engineering 32 1 12 17 In-text reference: (Wang & Zhang, 2010) Search in Google Scholar

[26] Wróblewski, A., & Trybała, P., & Banasiewicz, A., & Zawiślak, M., & Walerysiak, N., & Wodecki, J. (2023). Possibilities of 3D laser scanning data utilization for numerical analysis of airflow in mining excavations. IOP Conf. Ser.: Earth Environ. Sci. 1189 012009. https://doi.org/10.1088/1755-1315/1189/1/012009. In-text reference: (Wróblewski et al., 2023) WróblewskiA. TrybałaP. BanasiewiczA. ZawiślakM. WalerysiakN. WodeckiJ. 2023 Possibilities of 3D laser scanning data utilization for numerical analysis of airflow in mining excavations IOP Conf. Ser.: Earth Environ. Sci. 1189 012009. https://doi.org/10.1088/1755-1315/1189/1/012009. In-text reference: (Wróblewski et al., 2023) Search in Google Scholar

[27] Xu, J., & Cui, Z., & Qian, K., & Sun, X., & Xu, J. (2022). Three-Dimensional Numerical Analysis and Engineering Evaluation of Stilling Basin and Foundation Bedrock of Kala Hydropower Station, China. Front. Phys. 9:807506. https://doi.org/doi:10.3389/fphy.2021.807506 In-text reference: (Xu et al., 2022) XuJ. CuiZ. QianK. SunX. XuJ. 2022 Three-Dimensional Numerical Analysis and Engineering Evaluation of Stilling Basin and Foundation Bedrock of Kala Hydropower Station, China Front. Phys. 9 807506 https://doi.org/doi:10.3389/fphy.2021.807506 In-text reference: (Xu et al., 2022) Search in Google Scholar