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Rock Mechanics and Rock Engineering

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01.09.2015 | Original Paper

Numerical Simulation of Rock Mass Damage Evolution During Deep-Buried Tunnel Excavation by Drill and Blast

verfasst von: Jianhua Yang, Wenbo Lu, Yingguo Hu, Ming Chen, Peng Yan

Erschienen in: Rock Mechanics and Rock Engineering | Ausgabe 5/2015

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Abstract

Presence of an excavation damage zone (EDZ) around a tunnel perimeter is of significant concern with regard to safety, stability, costs and overall performance of the tunnel. For deep-buried tunnel excavation by drill and blast, it is generally accepted that a combination of effects of stress redistribution and blasting is mainly responsible for development of the EDZ. However, few open literatures can be found to use numerical methods to investigate the behavior of rock damage induced by the combined effects, and it is still far from full understanding how, when and to what degree the blasting affects the behavior of the EDZ during excavation. By implementing a statistical damage evolution law based on stress criterion into the commercial software LS-DYNA through its user-subroutines, this paper presents a 3D numerical simulation of the rock damage evolution of a deep-buried tunnel excavation, with a special emphasis on the combined effects of the stress redistribution of surrounding rock masses and the blasting-induced damage. Influence of repeated blast loadings on the damage extension for practical millisecond delay blasting is investigated in the present analysis. Accompanying explosive detonation and secession of rock fragments from their initial locations, in situ stress in the immediate vicinity of the excavation face is suddenly released. The transient characteristics of the in situ stress release and induced dynamic responses in the surrounding rock masses are also highlighted. From the simulation results, some instructive conclusions are drawn with respect to the rock damage mechanism and evolution during deep-buried tunnel excavation by drill and blast.

Vorheriger Artikel An Angle-Based Method Dealing with Vertex–Vertex Contact in the Two-Dimensional Discontinuous Deformation Analysis (DDA)

Nächster Artikel A Microseismic Method for Dynamic Warning of Rockburst Development Processes in Tunnels

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Blair DP (2009) Limitations of electronic delays for the control of blast vibration and fragmentation. In: Proceedings of the Ninth International Symposium Rock Fragm Blasting, Granada, Spain, 171–184

Blair DP (2010) Seismic radiation from an explosive column. Geophysics 75(1):55–65CrossRef

Cai M, Kaiser PK, Tasaka Y, Maejima T, Morioka H, Minami M (2004) Generalized crack initiation and crack damage stress thresholds of brittle rock masses near underground excavations. Int J Rock Mech Min Sci 41(5):833–847CrossRef

Cao WG, Fang ZL, Tang XJ (1998) A study of statistical constitutive model for soft and damage rocks. Chin J Rock Mech Eng 17(6):628–633 (in Chinese)

Carter JP, Booker JR (1990) Sudden excavation of a long circular tunnel in elastic ground. Int J Rock Mech Min Sci Geomech Abstr 27(2):129–132CrossRef

Cundall P, Hart R (1992) Numerical modelling of discontinua. Eng Comput 9(2):101–113CrossRef

Dare-Bryan PC, Mansfield S, Schoeman J (2012) Blast optimisation through computer modelling of fragmentation. In: Proceedings Tenth International Symposium Rock Fragm Blasting, New Delhi, India, 95–104

Falls SD, Young RP (1998) Acoustic emission and ultrasonic-velocity methods used to characterize the excavation disturbance associated with deep tunnels in hard rock. Tectonophysics 289(1):1–15CrossRef

Grady DE, Kipp ME (1980) Continuum modeling of explosive fracture in oil shale. Int J Rock Mech Min Sci Geomech Abstr 17(2):147–157CrossRef

Hamdi E, Romdhane NB, Le Cléac’h JM (2011) A tensile damage model for rocks: application to blast induced damage assessment. Comput Geotech 38(2):133–141CrossRef

Hao H, Ma G, Zhou Y (1998) Numerical simulation of underground explosions. Rock Fragm Blasting 2(4):383–395

He MC, Miao JL, Feng JL (2010) Rock burst process of limestone and its acoustic emission characteristics under true-triaxial unloading conditions. Int J Rock Mech Min Sci 47(2):286–298CrossRef

Henrych J, Major R (1979) The dynamics of explosion and its use. Elsevier Scientific Publishing Company, New York

Jaeger JC, Cook NGW, Zimmerman R (2009) Fundamentals of rock mechanics. Wiley, New York

Krajcinovic D, Silva MAG (1982) Statistical aspects of the continuous damage theory. Int J Solids Struct 18(7):551–562CrossRef

Kuhlemeyer RL, Lysmer J (1973) Finite element method accuracy for wave propagation problems. J Soil Mech Found Div 99(5):421–427

Kwon S, Lee CS, Cho SJ, Jeon SW, Cho WJ (2009) An investigation of the excavation damaged zone at the KAERI underground research tunnel. Tunn Undergr Space Technol 24(1):1–13CrossRef

Li HB, Xia X, Li JC, Zhao J, Liu B, Liu Y (2011) Rock damage control in bedrock blasting excavation for a nuclear power plant. Int J Rock Mech Min Sci 48(2):210–218CrossRef

Li S, Feng XT, Li Z, Zhang C, Chen B (2012) Evolution of fractures in the excavation damaged zone of a deeply buried tunnel during TBM construction. Int J Rock Mech Min Sci 55:125–138CrossRef

Liu L, Katsabanisj PD (1997) Development of a continuum damage model for blasting analysis. Int J Rock Mech Min Sci 34(2):217–231CrossRef

Lu W, Yang J, Yan P, Chen M, Zhou C, Luo Y, Jin L (2012) Dynamic response of rock mass induced by the transient release of in situ stress. Int J Rock Mech Min Sci 53:129–141CrossRef

Ma GW, An XM (2008) Numerical simulation of blasting-induced rock fractures. Int J Rock Mech Min Sci 45(6):966–975CrossRef

Martin CD, Kaiser PK, Mccreath DR (1999) Hoek-Brown parameters for predicting the depth of brittle failure around tunnels. Can Geotech J 36(1):136–151CrossRef

Martino JB, Chandler NA (2004) Excavation-induced damage studies at the Underground Research Laboratory. Int J Rock Mech Min Sci 41(8):1413–1426CrossRef

Minchinton A, Lynch, PM (1996) Fragmentation and heave modelling using a coupled discrete element gas flow code. In: Proceedings Fifth International Symposium Rock Fragm Blasting, Montreal, Canada, 71–80

Munjiza A (1992) Discrete elements in transient dynamics of fractured media. PhD thesis, University of Wales, University College of Swansea, Wales, UK

Nilson RH, Proffer WJ, Duff RE (1985) Modelling of gas driven fractures induced by propellant combustion within a borehole. Int J Rock Mech Min Sci 22(1):3–19CrossRef

Ning Y, Yang J, An X, Ma GW (2011) Modelling rock fracturing and blast-induced rock mass failure via advanced discretisation within the discontinuous deformation analysis framework. Comput Geotech 38(1):40–49CrossRef

Onederra IA, Furtney JK, Sellers E, Iverson S (2013) Modelling blast induced damage from a fully coupled explosive charge. Int J Rock Mech Min Sci 58:73–84

Owen DRJ, Munjiza A, Bicanic N (1992) A finite element-discrete element approach to the simulation of rock blasting problems. In: Proceedings of the Eleventh Symposium on Finite EIenient Methods in South Africa, Cape Town, 39–58

Pellet F, Roosefid M, Deleruyelle F (2009) On the 3D numerical modelling of the time-dependent development of the damage zone around underground galleries during and after excavation. Tunn Undergr Space Technol 24(6):665–674CrossRef

Ramulu M, Chakraborty AK, Sitharam TG (2009) Damage assessment of basaltic rock mass due to repeated blasting in a railway tunnelling project–a case study. Tunn Undergr Space Technol 24(2):208–221CrossRef

Shan Z, Yan P (2010) Management of rock bursts during excavation of the deep tunnels in Jinping II Hydropower Station. Bull Eng Geol Environ 69(3):353–363CrossRef

Taylor LM, Chen EP, Kuszmaul JS (1986) Microcrack-induced damage accumulation in brittle rock under dynamic loading. Comput Methods Appl Mech Eng 55(3):301–320CrossRef

Torano J, Rodríguez R, Diego I, Rivas JM, Casal MD (2006) FEM models including randomness and its application to the blasting vibrations prediction. Comput Geotech 33(1):15–28CrossRef

Villaescusa E, Onederra I, Scott C (2004) Blast induced damage and dynamic behavior of hangingwalls in bench stoping. Rock Fragm Blasting 8(1):23–40

Wang B, Garga VK (1993) A numerical method of modelling large displacements of jointed rocks. Part I: Fundamentals. Can Geotech J 30(1):96–108

Wang SH, Lee CI, Ranjith PG, Tang CA (2009) Modeling the effects of heterogeneity and anisotropy on the excavation damage/disturbed zone (EDZ). Rock Mech Rock Eng 42(2):229–258CrossRef

Wassermann J, Sabroux JC, Pontreau S, Bondiguel S, Guillon S, Richon P, Pili E (2011) Characterization and monitoring of the excavation damaged zone in fractured gneisses of the Roselend tunnel French Alps. Tectonophysics 503(1):155–164CrossRef

Wu C, Lu Y, Hao H (2004) Numerical prediction of blast-induced stress wave from large-scale underground explosion. Int J Numer Anal Methods Geomech 28(1):93–109CrossRef

Xia X, Li HB, Li JC, Liu B, Yu C (2013) A case study on rock damage prediction and control method for underground tunnels subjected to adjacent excavation blasting. Tunn Undergr Space Technol 35:1–7CrossRef

Yan P, Lu WB, Chen M, Shan ZG, Chen XR (2011) In-situ test research on influence of excavation method on induced damage zone in deep tunnel. Chin J Rock Mech Eng 30(6):1097–1106 (in Chinese)

Yang R, Bawden WF, Katsabanis PD (1996) A new constitutive model for blast damage. Int J Rock Mech Min Sci Geomech Abstr 33(3):245–254CrossRef

Yang J, Lu W, Chen M, Yan P, Zhou C (2013) Microseism induced by transient release of in situ stress during deep rock mass excavation by blasting. Rock Mech Rock Eng 46(4):859–875CrossRef

Zhang C, Feng X, Zhou H, Qiu S, Wu W (2012) A top pilot tunnel preconditioning method for the prevention of extremely intense rockbursts in deep tunnels excavated by TBMs. Rock Mech Rock Eng 45(3):289–309CrossRef

Titel: Numerical Simulation of Rock Mass Damage Evolution During Deep-Buried Tunnel Excavation by Drill and Blast
verfasst von: Jianhua Yang
Wenbo Lu
Yingguo Hu
Ming Chen
Peng Yan
Publikationsdatum: 01.09.2015
Verlag: Springer Vienna
Erschienen in: Rock Mechanics and Rock Engineering / Ausgabe 5/2015
Print ISSN: 0723-2632
Elektronische ISSN: 1434-453X
DOI: https://doi.org/10.1007/s00603-014-0663-0

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