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Rock Mechanics and Rock Engineering

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26.09.2016 | Original Paper

Modelling the Source of Blasting for the Numerical Simulation of Blast-Induced Ground Vibrations: A Review

verfasst von: Daniel Ainalis, Olivier Kaufmann, Jean-Pierre Tshibangu, Olivier Verlinden, Georges Kouroussis

Erschienen in: Rock Mechanics and Rock Engineering | Ausgabe 1/2017

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Abstract

The mining and construction industries have long been faced with considerable attention and criticism in regard to the effects of blasting. The generation of ground vibrations is one of the most significant factors associated with blasting and is becoming increasingly important as mining sites are now regularly located near urban areas. This is of concern to not only the operators of the mine but also residents. Mining sites are subjected to an inevitable compromise: a production blast is designed to fragment the utmost amount of rock possible; however, any increase in the blast can generate ground vibrations which can propagate great distances and cause structural damage or discomfort to residents in surrounding urban areas. To accurately predict the propagation of ground vibrations near these sensitive areas, the blasting process and surrounding environment must be characterised and understood. As an initial step, an accurate model of the source of blast-induced vibrations is required. This paper presents a comprehensive review of the approaches to model the blasting source in order to critically evaluate developments in the field. An overview of the blasting process and description of the various factors which influence the blast performance and subsequent ground vibrations are also presented. Several approaches to analytically model explosives are discussed. Ground vibration prediction methods focused on seed waveform and charge weight scaling techniques are presented. Finally, numerical simulations of the blasting source are discussed, including methods to estimate blasthole wall pressure time-history, and hydrodynamic codes.

Vorheriger Artikel New Rapid Evaluation for Long-Term Behavior in Deep Geological Repository by Geotechnical Centrifuge—Part 2: Numerical Simulation of Model Tests in Isothermal Condition

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Abo-Zena AM (1977) Radiation from a finite cylindrical explosive source. Geophysics 42:1384–1393CrossRef

Aimone C (1992) Rock breakage: explosives, blast design. In: Darling P (ed) SME mining engineering handbook, 3rd edn. Society of Mining Engineers, Littleton, pp 722–746

Aki K, Richards PG (2002) Quantitative seismology, 2nd edn. University Science Books, San Francisco

Aldas GGU (2010) Investigation of blast design parameters from the point of seismic signals. Int J Min Reclam Environ 24:80–90CrossRef

Ambraseys NN, Hendron AJ (1968) Dynamic behaviour of rock masses. In: Ambraseys NN (ed) Rock mechanics in engineering practice. Wiley, New York, pp 203–207

Anderson D (2008) Signature hole blast vibration control-twenty years hence and beyond. Paper presented at the 34th conference on explosives and blasting technique, Cleveland, pp 27–38

Anderson DA, Ritter AP, Winzer SR, Reil JW (1985) A method for site-specific prediction and control of ground vibration from blasting. Paper presented at the 11th annual conference on explosives and blasting techniques, San Diego

Anon (1999) National park service handbook for the transportation and use of explosives. National Park Service, Washington, DC

Auersch L, Said S (2010) Attenuation of ground vibrations due to different technical sources. Earthq Eng Vib 9:337–344CrossRef

Baird GR, Blair DP, Jiang J (1992) Particle motions on the surface of an elastic half-space due to a vertical column of explosives. Paper presented at the Western Australian conference of mining geomechanics, pp 367–374

Banadaki MD, Mohanty B (2012) Numerical simulation of stress wave induced fractures in rock. Int J Impact Eng 40:16–25CrossRef

Bergmann L, Hatfield H (1949) Ultrasonics and their scientific and technical applications. Wiley, New York

Bergmann O, Riggle J, Wu F (1973) Model rock blasting—effect of explosives properties and other variables on blasting results. Int J Rock Mech Min 6:585–612CrossRef

Bhagwat V, Mishra D, Pathak K, Dey K (2015) Vibration predictor equation—some issues. J Mines Met Fuels 63(7)

Bhandari S (1997) Engineering rock blasting operations. A.A. Balkema, Rotterdam

Birch W, White T, Hosein S (2010) Electronic detonators: a step forward in blast vibration control. Paper presented at the 15th extractive industry geology conference, Cardiff

Blair DP (1987) The measurement, modelling and control of ground vibrations due to blasting. Paper presented at the 2nd international symposium of rock fragmentation by blasting, Colorado, pp 88–101

Blair DP (1990) Some problems associated with standard charge weight vibration scaling laws. Paper presented at the 3rd international symposium on fragmentation by blasting, Brisbane, pp 149–158

Blair DP (1993) Blast vibration control in the presence of delay scatter and random fluctuations between blastholes. Int J Numer Anal Met 17:95–118CrossRef

Blair DP (1999) Statistical models for ground vibration and airblast. Fragblast 3:335–364CrossRef

Blair DP (2003) A fast and efficient solution for wave radiation from a pressurised blasthole. Fragblast 7:205–230CrossRef

Blair DP (2004a) The frequency content of ground vibration. Fragblast 8:151–176CrossRef

Blair DP (2004b) Charge weight scaling laws and the superposition of blast vibration waves. Fragblast 8:221–239CrossRef

Blair DP (2007) A comparison of Heelan and exact solutions for seismic radiation from a short cylindrical charge. Geophysics 72:E33–E41CrossRef

Blair DP (2008) Non-linear superposition models of blast vibration. Int J Rock Mech Min 45:235–247CrossRef

Blair DP (2009) Limitations of electronic delays for the control of blast vibration and fragmentation. Paper presented at the 9th international symposium on rock fragmentation by blasting, Granada

Blair DP (2010) Seismic radiation from an explosive column. Geophysics 75:E55–E65CrossRef

Blair DP (2011) A probabilistic analysis of vibration based on measured data and charge weight scaling. Paper presented at the EFEE 6th world conference on explosives and blasting technique, Lisbon

Blair DP (2014) Blast vibration dependence on charge length, velocity of detonation and layered media. Int J Rock Mech Min 65:29–39

Blair DP (2015a) The free surface influence on blast vibration. Int J Rock Mech Min 77:182–191

Blair DP (2015b) Wall control blasting. Paper presented at the 11th international symposium on rock fragmentation by blasting, Sydney, pp 13–26

Blair DP, Armstrong LW (1999) The spectral control of ground vibration using electronic delay detonators. Fragblast 3:303–334CrossRef

Blair DP, Armstrong LW (2001) The influence of burden on blast vibration. Fragblast 5:108–129CrossRef

Blair DP, Birney B (1994) Vibration signatures due to single blastholes fired in the Charlotte Deeps. ICI Confidential Report

Blair DP, Jiang J (1995) Surface vibrations due to a vertical column of explosive. Int J Rock Mech Min 32:149–154CrossRef

Blair DP, Minchinton A (1997) On the damage zone surrounding a single blasthole. Fragblast 1:59–72CrossRef

Blake FG (1952) Spherical wave propagation in solid media. J Acoust Soc Am 24:211–215CrossRef

Bobet A, Fakhimi A, Johnson S, Morris J, Tonon F, Yeung MR (2009) Numerical models in discontinuous media: review of advances for rock mechanics applications. J Geotech Geoenviron 135:1547–1561CrossRef

Bowen N (2015) Next generation blasting—how will wireless change mining? Paper presented at the 2nd annual international mining and resources conference, Melbourne

Braithwaite M (2012) Ideal detonation reaction concepts for blasting engineers. In: Mohanty B, Singh VK (eds) Performance of explosives and new developments. CRC Press, London

Brent G, Smith G, Lye G (2002) Studies on the effect of burden on blast damage and the implementation of new blasting practices to improve productivity at KCGMs Fimiston Mine. Fragblast 6:189–206CrossRef

Cavanough G, Onederra I (2011) Development of pressure and temperature gauges to monitor in situ performance of commercial explosives. Min Technol 120:74–79CrossRef

Chiappetta R (1994) New findings on the impact of an explosive VOD on blast results. Paper presented at the 20th conference on explosives and blasting technique, Austin

Cho SH, Kaneko K (2004) Influence of the applied pressure waveform on the dynamic fracture processes in rock. Int J Rock Mech Min 41:771–784CrossRef

Clark GB (1987) Principles of rock fragmentation. Wiley, New York

Connolly DP, Kouroussis G, Laghrouche O, Ho CL, Forde MC (2015) Benchmarking railway vibrations—track, vehicle, ground and building effects. Constr Build Mater 92:64–81CrossRef

Cook NGW (1992) Natural joints in rock: mechanical, hydraulic and seismic behaviour and properties under normal stress. Int J R Mech Min 29:198–223CrossRef

Cooper PW (1996) Explosives engineering. Wiley, New York

Crenwelge O (1988) Use of single charge vibration data to interpret explosive excitation and ground transmission characteristics. Paper presented at the 14th conference on explosives and blasting technique, Anaheim

Dehghani H, Ataee-Pour M (2011) Development of a model to predict peak particle velocity in a blasting operation. Int J Rock Mech Min 48:51–58CrossRef

Dick RA, Fletcher LR, D’Andrea DV (1983) Explosives and blasting procedures manual. Information Circulation 8925, Bureau of Mines, United States Department of the Interior

Ding H, Labbas R, Zheng Z (2005) Features of blast-induced vibration source and identification of geostructures. J Sound Vib 288:91–106CrossRef

Donzé FV, Bouchez J, Magnier SA (1997) Modeling fractures in rock blasting. Int J Rock Mech Min 34:1153–1163CrossRef

Dowding CH (1985) Blast vibration monitoring and control. Prentice-Hall, Englewood Cliffs

Dowding CH, Aimone CT (1985) Multiple blast-hole stresses and measured fragmentation. Rock Mech Rock Eng 18:17–36CrossRef

Duvall WI (1953) Strain-wave shapes in rock near explosions. Geophysics 18:310–323CrossRef

Duvall WI, Fogelson DE (1962) Review of criteria for estimating damage to residences from blasting vibrations. Bureau of Mines, College Park

Edwards AT, Northwood TD (1960) Experimental studies of the effects of blasting on structures. Engineer 210:538–546

Esen S, Onederra I, Bilgin HA (2003) Modelling the size of the crushed zone around a blasthole. Int J Rock Mech Min 40:485–495CrossRef

Fakhimi A, Lanari M (2014) DEM-SPH simulation of rock blasting. Comput Geotech 55:158–164CrossRef

Favreau RF (1969) Generation of strain waves in rock by an explosion in a spherical cavity. J Geophys Res 74:4267–4280CrossRef

Fleetwood KG (2010) Near-field blast vibration monitoring and analysis for prediction of blast damage in sublevel open stoping. PhD Dissertation, Curtin University

Gao M, Wang Y, Gao G, Yang J (2013) An analytical solution for the transient response of a cylindrical lined cavity in a poroelastic medium. Soil Dyn Earthq Eng 46:30–40CrossRef

Gu B, Suárez-Rivera R, Nihei KT, Myer LR (1996) Incidence of plane waves upon a fracture. J Geophys Res 101:25337–25346CrossRef

Gutowski TG, Dym CL (1976) Propagation of ground vibration: a review. J Sound Vib 49:179–193CrossRef

Hagan TN (1979) Rock breakage by explosives. Acta Astronaut 6:329–340CrossRef

Hao H, Wu C, Zhou Y (2002) Numerical analysis of blast-induced stress waves in a rock mass with anisotropic continuum damage models part 1: equivalent material property approach. Rock Mech Rock Eng 35:79–94CrossRef

Harries G (1983) The modelling of long cylindrical charges of explosive. Paper presented at the 1st international symposium on rock fragmentation by blasting, Lulea

Heelan PA (1953) Radiation from a cylindrical source of finite length. Geophysics 18:685–696CrossRef

Hinzen K-G (1988) Modelling of blast vibrations. Int J Rock Mech Min 25:439–445CrossRef

Hinzen K-G, Luedeling R, Heinemeyer F, Roch P, Steiner U (1987) A new approach to predict and reduce blast vibration by modelling of seismograms and using a new electronic initiation system. Paper presented at the 13th Conference on Explosives and Blasting Technique, Miami, pp 144–161

Hopler RB (1998) Blasters’ handbook, 17th edn. International Society of Explosives Engineers, Cleveland

Hunaidi O, Guan W, Nicks J (2000) Building vibrations and dynamic pavement loads induced by transit buses. Soil Dyn Earthq Eng 19:435–453CrossRef

Hustrulid W (1999) Blasting principles for open-pit blasting: theoretical foundations, vol 2. Balkema, Rotterdam

ISO (2010) ISO 4866: mechanical vibration and shock—vibration of fixed structures—guidelines for the measurement of vibrations and evaluation of their effects on structures. International Organisation for Standardisation ISO, Geneva

Jiang J, Blair DP, Baird GR (1995) Dynamic response of an elastic and viscoelastic full-space to a spherical source. Int J Numer Anal Met 19:181–193CrossRef

Jommi C, Pandolfi A (2008) Vibrations induced by blasting in rock: a numerical approach. Rev Ital Geotec 20:77–94

Jong Y, Lee C, Jeon S, Cho Y, Shim D (2005) Numerical modeling of the circular-cut using particle flaw code. Paper presented at the 31st annular conference of explosives and blasting technique, Orlando

Keith CM, Crampin S (1977) Seismic body waves in anisotropic media: propagation through a layer. Geophys J Int 49:209–223CrossRef

Khandelwal M, Singh TN (2006) Prediction of blast induced ground vibrations and frequency in opencast mine: a neural network approach. J Sound Vib 289:711–725CrossRef

Khandelwal M, Singh TN (2007) Evaluation of blast-induced ground vibration predictors. Soil Dyn Earthq Eng 27:116–125CrossRef

Kim D-S, Lee J-S (2000) Propagation and attenuation characteristics of various ground vibrations. Soil Dyn Earthq Eng 19:115–126CrossRef

Kjartansson E (1979) Constant Q-wave propagation and attenuation. J Geophys Res 84:4737–4748CrossRef

Kouroussis G, Verlinden O, Conti C (2012) Influence of some vehicle and track parameters on the environmental vibrations induced by railway traffic. Veh Syst Dyn 50:619–639CrossRef

Kury JW, Hornig HC, Lee EL, McDonnel JL, Ornellas DL, Finger M, Strange FM, Wilkins ML (1965) Metal acceleration by chemical explosives. Paper presented at the 4th international symposium on detonation, pp 3–10

Kutter HK, Fairhurst C (1971) On the fracture process in blasting. Int J Rock Mech Min 8:181–202CrossRef

Lak MA, François S, Degrande G, Lombaert G (2015) Development and experimental validation of a numerical model for the prediction of ground vibration generated by pavement breaking. Soil Dyn Earthq Eng 79(Part A):199–210CrossRef

Langefors U, Kihlström B (1963) The modern technique of rock blasting. Wiley, New York

Lee JH (2008) The detonation phenomenon. Cambridge University Press, CambridgeCrossRef

Lee N (2011) The effects of various wet-hole loading methods on powder factor. Paper presented at the 37th conference on explosives and blasting technique, San Diego

Lee E, Hornig H, Kury J (1968) Adiabatic expansion of high explosive detonation products. California University, Lawrence Radiation Lab, LivermoreCrossRef

Liu L (1997) Continuum modelling of rock fragmentation by blasting. PhD Dissertation, Queen’s University

Liu Q, Ludwig G (1996) A blast damage study in blasthole open stope mining. Paper presented at the 5th international symposium on rock fragmentation by blasting, Montreal

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

Ma GW, Hao H, Zhou YX (1998) Modeling of wave propagation induced by underground explosion. Comput Geotech 22:283–303CrossRef

Malischewsky PG (2005) Comparison of approximated solutions for the phase velocity of Rayleigh waves. Nanotechnology 16:995–996CrossRef

Mandal SK (2012) Mathematical model to locate interference of blast waves from multi-hole blasting rounds. Engineering 4:146–154CrossRef

Masoumi HR, Degrande G (2008) Numerical modeling of free field vibrations due to pile driving using a dynamic soil-structure interaction formulation. J Comput Appl Math 215:503–511CrossRef

Meredith JA, Toksöz MN, Cheng CH (1993) Secondary shear waves from source boreholes. Geophys Prospect 41:287–312CrossRef

Mesec J, Žganec S, Kovač I (2015) In-hole velocity of detonation (VOD) measurements as a framework for the selection type of explosive. Int J Min Sci Technol 25:675–680CrossRef

Minchinton, A (2015) On the influence of fundamental detonics on blasting practice. Paper presented at the 11th international symposium on rock fragmentation by blasting, Sydney, pp 41–53

Mitelman A, Elmo D (2014) Modelling of blast-induced damage in tunnels using a hybrid finite-discrete numerical approach. J Rock Mech Geotech Eng 6:565–573CrossRef

Mohamadnejad M, Gholami R, Ataei M (2012) Comparison of intelligence science techniques and empirical methods for prediction of blasting vibrations. Tunn Underg Space Technol 28:238–244CrossRef

Monjezi M, Ahmadi M, Sheikhan M, Bahrami A, Salimi AR (2010) Predicting blast-induced ground vibration using various types of neural networks. Soil Dyn Earthq Eng 30:1233–1236CrossRef

Müller TM, Gurevich B, Lebedev M (2010) Seismic wave attenuation and dispersion resulting from wave-induced flow in porous rocks—a review. Geophysics 75:75A147–175A164CrossRef

Nicholls HR, Johnson CF, Duvall WI (1971) Blasting vibrations and their effects on structures. Bureau of Mines, Denver Mining Research Center, Denver

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

Ouchterlony F, Moser P (2013) Lessons from single-hole blasting in mortar, concrete and rocks. Paper presented at the 10th international symposium on rock fragmentation by blasting, New Delhi

Ozer U, Karadogan A, Kalyci U, Aksoy M, Keti Z (2012) The effects of fault planes on the propagation of vibration waves. Paper presented at the 38th conference on explosives and blasting technique, Nashville

Park D, Jeon S (2010) Reduction of blast-induced vibration in the direction of tunneling using an air-deck at the bottom of a blasthole. Int J Rock Mech Min 47:752–761CrossRef

Park D, Jeon B, Jeon S (2009) A numerical study on the screening of blast-induced waves for reducing ground vibration. Rock Mech Rock Eng 42:449–473CrossRef

Persson P-A, Holmberg R, Lee J (1993) Rock blasting and explosives engineering. CRC Press, Boca Raton

Plewman RP, Starfield AM (1965) The effects of finite velocities of detonation and propagation on the strain pulses induced in rock by linear charges. J S Afr I Min Metall 66:77–96

Pramanik R, Deb D (2015) Implementation of smoothed particle hydrodynamics for detonation of explosive with application to rock fragmentation. Rock Mech Rock Eng 48:1683–1698CrossRef

Pyrak-Nolte LJ, Myer LR, Cook NG (1990a) Transmission of seismic waves across single natural fractures. J Geophys Res 95:8617–8638CrossRef

Pyrak-Nolte LJ, Myer LR, Cook NG (1990b) Anisotropy in seismic velocities and amplitudes from multiple parallel fractures. J Geophys Res 95:11345–11358CrossRef

Rahman M, Michelitsch T (2006) A note on the formula for the Rayleigh wave speed. Wave Motion 43:272–276CrossRef

Resende R, Lamas L, Lemos J, Calçada R (2014) Stress wave propagation test and numerical modelling of an underground complex. Int J Rock Mech Min 72:26–36

Rinehart JS, Fortin J, Burgin L (1961) Propagation velocity of longitudinal waves in rocks. Effect of state of stress, stress level of the wave, water content, porosity, temperature, stratification and texture. Colorado School of Mines Research Foundation, Golden

Rossmanith HP, Kouzniak N (2004) Supersonic detonation in rock mass—part 2: particle displacements and velocity fields for single and multiple non-delayed and delayed detonating blastholes. Fragblast 8:95–117CrossRef

Rouse NT (2015) The relative effect of charge dimensions on elastic vibration attenuation and blast-induced seismic energy concepts. PhD Dissertation, Missouri University of Science and Technology

Saharan RM, Mitri SH (2008) Numerical procedure for dynamic simulation of discrete fractures due to blasting. Rock Mech Rock Eng 41:641–670CrossRef

Sainoki A, Mitri HS (2014) Numerical simulation of rock mass vibrations induced by nearby production blast. C Geotech J 51:1253–1262CrossRef

Semblat JF (2010) Modeling seismic wave propagation and amplification in 1D/2D/3D linear and nonlinear unbounded media. Int J Geomech 11:440–448CrossRef

Shao S, Petrovitch C, Pyrak-Nolte L (2015) Wave guiding in fractured layered media. Geol Soc Lond Spec Publ 406:375–400CrossRef

Sharpe JA (1942) The production of elastic waves by explosion pressures. I. Theory and empirical field observations. Geophysics 7:144–154CrossRef

Shekhar H (2012) Studies on empirical approaches for estimation of detonation velocity of high explosives. Cent Eur J Energ Mater 9:39–48

Shi XZ, Chen SR (2011) Delay time optimization in blasting operations for mitigating the vibration-effects on final pit walls’ stability. Soil Dyn Earthq Eng 31:1154–1158CrossRef

Silva-Castro JJ (2012) Blast vibration modeling using improved signature hole technique for bench blast. PhD Dissertation, University of Kentucky

Singh P, Narendrula R (2007) The influence of rock mass quality in controlled blasting. Paper presented at the 26th international conference on ground control in mining, Morgantown, pp 314–319

Siskind DE, Fumanti RR (1974) Blast-produced fractures in Lithonia granite. U.S. Department of the Interior, New York

Siskind DE, Stachura V, Nutting M (1985) The generation of low-frequency long-duration vibrations from surface mine blasting at blanford. US Bureau of Mines, Washington, DC

Siskind DE, Crum SV, Otterness RE, Kopp JW (1989) Comparative study of blasting vibrations from Indiana surface coal mines. US Bureau of Mines, Washington, DC

Spathis AT (2009) A brief review of the measurement, modelling and management of vibrations produced by blasting. Paper presented at the 9th international symposium on rock fragmentation by blasting, Granada, pp 1–11

Srbulov M (2008) Geotechnical earthquake engineering: simplified analyses with case studies and examples. Springer, Berlin

Standards BoI (1973) Criteria for safety and design of structures subjected to under ground blast. Bureau of Indian Standards, New Delhi

Starfield AM, Pugliese JM (1968) Compression waves generated in rock by cylindrical explosive charges: a comparison between a computer model and field measurements. Int J Rock Mech Min 5:65–77CrossRef

Svinkin MR (2008) Soil and structure vibrations from construction and industrial sources. Paper presented at the 6th international conference on case histories in geotechnical engineering, Arlington

Taqieddin SA (1986) Ground vibration levels: prediction and parameters. Min Sci Technol 3:111–115CrossRef

Tete AD, Deshmukh A, Yerpude R (2016) Design and implementation of electronic sensor for velocity-of-detonation measurement of cartridge explosive and comparison with Dautriche method. Int J Min Miner Eng 7:113–125CrossRef

Trivino LF (2012) Study of blast-induced damage in rock with potential application to open pit and underground mines. PhD Dissertation, University of Toronto

Trivino L, Mohanty B, Munjiza (2009) A Seismic radiation patterns from cylindrical explosive charges by combined analytical and combined finite-discrete element methods. Paper presented at the 9th international symposium on rock fragmentation by blasting, Granada, pp 415–426

Tubman KM, Cheng CH, Toksoez MN (1984) Synthetic full waveform acoustic logs in cased boreholes. Geophysics 49:1051–1059CrossRef

Uysal Ö, Arpaz E, Berber M (2007) Studies on the effect of burden width on blast-induced vibration in open-pit mines. Environ Geol 53:643–650CrossRef

Valliapan S, Lee IK, Murti V, Ang KK, Ross AH (1983) Numerical modelling of rock fragmentation. Paper presented at the 1st international symposium on rock fragmentation by blasting, Lulea, pp 375–390

Vanbrabant F, Chacón EP, Quiñones LA (2002) P and s mach waves generated by the detonation of a cylindrical explosive charge—experiments and simulations. Fragblast 6:21–35CrossRef

Verma AK, Singh TN (2011) Intelligent systems for ground vibration measurement: a comparative study. Eng Comput 27:225–233CrossRef

Walter E, Carroll J (1981) Lithologic variation and vibration effects. Paper presented at the 7th conference on explosives and blasting technique, Phoenix

Wang ZL, Konietzky H (2009) Modelling of blast-induced fractures in jointed rock masses. Eng Fract Mech 76:1945–1955CrossRef

Ward JH (1963) Hierarchical grouping to optimize an objective function. J Am Stat Assoc 58:236–244CrossRef

Wheeler RM (2001) The analysis of signature vibrations to help control vibration frequency. Paper presented at the 10th high-tech seminar on the state of the art blasting technology, Nashville

Worsey PN (1986) Understanding vibrations from multihole blasts using short delay periods. J Explos Eng 3:25–28

Yang RL (2011) Modeling effect of delay scatter on peak particle velocity of blast vibration using a multiple seed waveform vibration model. Blast Fragm 5:31–45

Yang RL, Scovira DS (2007) A model for near-field blast vibration based on signal broadening and amplitude attenuation. Paper presented at explo 2007, Wollongong, pp 59–66

Yang RL, Scovira DS (2008) A model to predict the peak particle velocity for near field blast vibration-based on dominant charge, waveform broadening, delay time modeling, and non-linear charge weight superposition. Blast Fragm 2:91–116

Yang RL, Scovira DS (2010) A model for near and far-field blast vibration based on multiple seed waveforms and transfer functions. Blast Fragm 4:91–116

Yang RL, Rocque P, Katsabanis P, Bawden WF (1994) Measurement and analysis of near-field blast vibration and damage. Geotech Geol Eng 12:169–182CrossRef

Yang RL, Whitaker T, McMullin B, Gunderson JA (2008) A case study of near field vibration monitoring, analysis and modeling. Blast Fragm 3:21–42

Yang RL, Scovira DS, Patterson NJ (2009) An integrated approach of signature hole vibration monitoring and modeling for quarry vibration control. Paper presented at the 9th international symposium on rock fragmentation by blasting, Granada

Yi C, Johansson D, Nyberg U, Beyglou A (2015) Stress wave interaction between two adjacent blast holes. Rock Mech Rock Eng 49:1803–1812CrossRef

Yilmaz O, Unlu T (2013) Three dimensional numerical rock damage analysis under blasting load. Tunn Undegr Space Technol 38:266–278CrossRef

Yuill GJ (2003) Simulation of the generation and propagation of blast induced shock waves. PhD Dissertation, University of Leeds

Titel: Modelling the Source of Blasting for the Numerical Simulation of Blast-Induced Ground Vibrations: A Review
verfasst von: Daniel Ainalis
Olivier Kaufmann
Jean-Pierre Tshibangu
Olivier Verlinden
Georges Kouroussis
Publikationsdatum: 26.09.2016
Verlag: Springer Vienna
Erschienen in: Rock Mechanics and Rock Engineering / Ausgabe 1/2017
Print ISSN: 0723-2632
Elektronische ISSN: 1434-453X
DOI: https://doi.org/10.1007/s00603-016-1101-2

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