Abstract
Blasting is sometimes inevitable in civil engineering work, to fragment the massive rock to enable excavation and leveling. In Minyak Beku, Batu Pahat also, blasting is implemented to fragment the rock mass, to reduce the in situ rock level to the required platform for a building construction. However, during blasting work, some rocks get an excessive amount of explosive energy and this energy may generate flyrock. An accident occurred on 15 July 2015 due to this phenomenon, in which one of the workers was killed and two other workers were seriously injured after being hit by the flyrock. The purpose of this study is to investigate the causes of the flyrock accidents through evaluation of rock mass geological structures. The discontinuities present on the rock face were analyzed, to study how they affected the projection and direction of the flyrock. Rock faces with lower mean joint spacing and larger apertures caused excessive flyrock. Based on the steoreonet analysis, it was found that slope failures also produced a significant effect on the direction, if the rock face failure lay in the critical zone area. Empirical models are often used to predict flyrock projection. In this study five empirical models are used to compare the incidents. It was found that none of the existing formulas could accurately predict flyrock distance. Analysis shows that the gap between predicted and actual flyrock can be reduced by including blast deign and geological conditions in forecasts. Analysis revealed only 69% of accuracy could be achieved if blast design is the only parameter to be considered in flyrock projection and the rest is influenced by the geological condition. Other causes of flyrock are discussed. Comparison of flyrock prediction with face bursting, cratering and rifling is carried out with recent prediction models.
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(Reproduced with permission from Mohamad et al. 2013)
(Reproduced with permission from Mohamad et al. 2013)
(Reproduced with permission from Mohamad et al. 2013)
(Reproduced with permission from Mohamad et al. 2013)
(Reproduced with permission from Little 2007)
(Reproduced with permission from Mohamad et al. 2013)
(Reproduced with permission from Armaghani et al. 2016)
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References
Abdullah RA, Rosle QA, Al-Bared MA, Haron NH, Kamal M, Ghazali M (2015) Stability assessment of rock slope at pangsapuri intan, cheras. In: International conference on slopes Malaysia, 14–16 Sept
Adhikari GR (1999) Studies on flyrock at limestone quarries. Rock Mech Rock Eng 32(4):291–301
Armaghani DJ, Mohamad ET, Hajihassani M, Abad SANK, Marto A, Moghaddam MR (2016) Evaluation and prediction of flyrock resulting from blasting operations using empirical and computational methods. Eng Comput 32(1):109–121
Bagchi A, Gupta RN (1990) Surface blasting and its impact on environmental. In: Workshop on Environmental Management of Mining Operations, Varanasi, pp 262–279
Bajpayee T, Rehak T, Mowrey G, Ingram D (2002) A summary of fatal accidents due to flyrock and lack of blast area security in surface mining, 1989 to 1999. In: Proceedings of the annual conference on explosives and blasting technique, vol 2. ISEE, 1999, pp 105–118
Bajpayee TS, Rehak TR, Mowrey GL, Ingram DK (2004) Blasting injuries in surface mining with emphasis on flyrock and blast area security. J Saf Res 35(1):47–57
Bhandari S (1997) Engineering rock blasting operations. A. A. Balkema, Rotterdam, p 388
Bhandari S, Muscat O (1994) Flyrock during blasting operations: controllable environmental hazards. In: Proceedings of the 2nd national seminar on minerals and ecology. Oxford and IBH Publishing, New Delhi, pp 279–308
Davitt AL, Simon JR (1983) U.S. Patent No. 4,406,226. U.S. Patent and Trademark Office, Washington, DC
Dick RA, Fletcher LR, D’Andrea DV (1982) Explosives and blasting procedures manual. US Department of the Interior, Bureau of Mines, Washington, DC
Favreau RF (1993) The prediction of the blast-induced swell by means of the computer simulations. Bull Can Inst Min Metall 86:69
Fletcher LR, D’Andrea DV (1987) Reducing accident through improved blasting safety. In: Proceedings of the bureau of mines technology transfer sem, pp 6–18
Ghasemi E, Sari M, Ataei M (2012) Development of an empirical model for predicting the effects of controllable blasting parameters on flyrock distance in surface mines. Int J Rock Mech Min Sci 52:163–170
Hagan TN (1983) The influence of controllable blast parameters on fragmentation and mining costs. In: Proceedings of the 1st international symposium on rock fragmentation by blasting, vol 1, pp 31–32
Hemphill GB (1981) Blasting operations. McGraw-Hill Companies, New York
Hoshino T, Mogi G, Shaoquan K (2000) Optimum delay interval design in delay blasting. Fragblast 4(2):139–148
Jimeno CL, Jimeno EL, Carcedo FJA, De Ramiro YV (1995) Drilling and blasting of rocks, geomining technological institute of Spain. AA Balkema, Rotterdam
Kecojevic V, Radomsky M (2005) Flyrock phenomena and area security in blasting related accidents. Saf Sci 43(9):739–750
Konya CJ, Walter EJ (1990) Surface blast design. Prentice-Hall, Englewood Cliffs
Kopp JW (1994) Observations of fly rock at several mines and quarries (No. CONF. 940144--). International Society of Explosives Engineers, Cleveland, OH (United States)
Little TN (2007) Flyrock risk. In: Proceedings EXPLO, pp 3–4
Lundborg N, Persson A, Ladegaard-Pedersen A, Holmberg R (1975) Keeping the lid on flyrock in open-pit blasting. Eng Min J 176:95–100
Manzoor SH, Choudhary BS (2014) Int J Res Aeronaut Mech Eng
Mishra AK, Rout M (2011) Flyrocks–detection and mitigation at construction site in blasting operation. World Environ 1(1):1–5
Mohamad ET, Armaghani DJ, Noorani SA, Saad R, Alvi SV, Abad NK (2012) Prediction of flyrock in boulder blasting using artificial neural network. EJGE 17(2012):2585–2595
Mohamad ET, Armaghani DJ, Motaghedi H (2013) The effect of geological structure and powder factor in flyrock accident, Masai, Johor, Malaysia. Electron J Geotechnol Eng 18:5561–5572
Mohamad ET, Murlidhar BR, Armaghani DJ, Saad R, Yi CS (2016) Effect of geological structure and blasting practice in flyrock accident at Johor, Malaysia. Jurnal teknologi 78(8–6):15–21
Monjezi M, Dehghani H, Singh TN, Sayadi AR, Gholinejad A (2012) Application of TOPSIS method for selecting the most appropriate blast design. Arab J Geosci 5(1):95–101
Monjezi M, Mehrdanesh A, Malek A, Khandelwal M (2013) Evaluation of effect of blast design parameters on flyrock using artificial neural networks. Neural Comput Appl 23(2):349–356
Olofsson SO (1990) Applied explosives technology for construction and mining. Nora Boktryckeri AB, Swden
Raina AK, Chakraborty AK, More R, Choudhury PB (2007) Design of factor of safety based criterion for control of flyrock/throw and optimum fragmentation. J Inst Eng India 87:13–17
Raina AK, Chakraborty AK, Choudhury PB, Sinha A (2011) Flyrock danger zone demarcation in opencast mines: a risk based approach. Bull Eng Geol Environ 70(1):163–172
Raina AK, Murthy VMSR, Soni AK (2014) Flyrock in bench blasting: a comprehensive review. Bull Eng Geol Environ 73(4):1199–1209
Raina AK, Murthy VMSR, Soni AK (2015) Flyrock in surface mine blasting: understanding the basics to develop a predictive regime. Curr Sci 108(4):660–665
Rehak T, Bajpayee T, Mowrey G, Ingram D (2001) Flyrock issues in blasting. In: Proceedings of the annual conference on explosives and blasting technique, vol 1. ISEE, 1999, pp 165–176
Richards A, Moore A (2004) Flyrock control-by chance or design. In: proceedings of the annual conference on explosives and blasting technique, vol 1. ISEE, 1999, pp 335–348
Richards AJ, Moore AB (2005) Golden pike cut back fly rock control and calibration of a predictive model. Terrock Consulting Engineers Report, Kalgoorlie Consolidated Gold Mines, 37
Siskind DE, Kopp JW (1995). Blasting accidents in mines, a 16-year summary (No. CONF-950247–). International Society of Explosives Engineers, Cleveland
St.George JD, Gibson MFL (2001) Estimation of flyrock travel distances: probabilistic approach. In: AusIMM EXPLO 2001 conference, Hunter Valley, pp 409–415
Stojadinović S, Pantović R, Žikić M (2011) Prediction of flyrock trajectories for forensic applications using ballistic flight equations. Int J Rock Mech Min Sci 48(7):1086–1094
Tatone BS, Grasselli G (2010) ROCKTOPPLE: a spreadsheet-based program for probabilistic block-toppling analysis. Comput Geosci 36(1):98–114
Trivedi R, Singh TN, Raina AK (2014) Prediction of blast-induced flyrock in Indian limestone mines using neural networks. J Rock Mech Geotech Eng 6(5):447–454
Venkatesh HS, Bhatawdekar RM, Adhikari GR, Theresraj AI (1999) Assessment and mitigation of ground vibrations and flyrock at a limestone quarry. In: Proceedings of the annual conference on explosives and blasting technique, vol. 2. International society of explosives engineers, pp 145–152
Verakis HC, Lobb TE (2003) An analysis of blasting accidents in mining operations. In: Proceedings of the 29th annual conference on explosives and blasting technique, 2003. International Society of Explosives Engineers, Cleveland, pp 119–129
Verakis H, Lobb T (2007) Flyrock revisited: an ever-present danger in mine blasting. In: proceedings of the annual conference on explosives and blasting technique, vol 33(1). ISEE, 1999, p 87
Workman JL, Calder PN (1994) Flyrock prediction and control in surface mine blasting (No. CONF-940144–). International Society of Explosives Engineers, Cleveland
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Mohamad, E.T., Yi, C.S., Murlidhar, B.R. et al. Effect of Geological Structure on Flyrock Prediction in Construction Blasting. Geotech Geol Eng 36, 2217–2235 (2018). https://doi.org/10.1007/s10706-018-0457-3
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DOI: https://doi.org/10.1007/s10706-018-0457-3