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Nondestructive Testing and Evaluation Volume 34, 2019 - Issue 4
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Original Articles

A new approach for estimation of rock brittleness based on non-destructive tests

Mohammadreza KoopialipoorFaculty of Civil and Environmental Engineering, Amirkabir University of Technology, Tehran, Iran
,
Amin NoorbakhshDepartment of Petroleum Engineering, Amirkabir University of Technology, Tehran, Iran
,
Ebrahim Noroozi GhaleiniFaculty of Mining and Metallurgy, Amirkabir University of Technology, Tehran, Iran
,
Danial Jahed ArmaghaniInstitute of Research and Development, Duy Tan University, Da Nang, VietnamCorrespondence[email protected]
&
Saffet YagizSchool of Mining and Geosciences, Nazarbayev University, Nur-Sultan city, Kazakhstan
Pages 354-375 | Received 26 Oct 2018, Accepted 24 Apr 2019, Published online: 04 Jun 2019

References

  • Miskimins JL. The impact of mechanical stratigraphy on hydraulic fracture growth and design considerations for horizontal wells. Bulletin. 2012;91:475–499.
  • Rickman R, Mullen MJ, Petre JE, et al. A practical use of shale petrophysics for stimulation design optimization: all shale plays are not clones of the Barnett Shale. SPE Annu. Tech. Conf. Exhib.; Sep 21–24; Denver, USA. Society of Petroleum Engineers; 2008.
  • Wang Y, Watson R, Rostami J, et al. Study of borehole stability of Marcellus shale wells in longwall mining areas. J Pet Explor Prod Technol. 2014;4:59–71.
  • Rybacki E, Reinicke A, Meier T, et al. What controls the mechanical properties of shale rocks?–part I: strength and Young’s modulus. J Pet Sci Eng. 2015;135:702–722.
  • Rybacki E, Meier T, Dresen G. What controls the mechanical properties of shale rocks?–part II: brittleness. J Pet Sci Eng. 2016;144:39–58.
  • Hajiabdolmajid V, Kaiser P. Brittleness of rock and stability assessment in hard rock tunneling. Tunnelling Underground Space Technol. 2003;18:35–48.
  • Kidybiński A. Bursting liability indices of coal. Int J Rock Mech Min Sci Geomech Abstr. 1981;18:295–304. Elsevier
  • Singh SP. Brittleness and the mechanical winning of coal. Min Sci Technol. 1986;3:173–180.
  • Singh SP. Burst energy release index. Rock Mech Rock Eng. 1988;21:149–155.
  • Yagiz S. Development of rock fracture and brittleness indices to quantify the effects of rock mass features and toughness in the CSM Model basic penetration for hard rock tunneling machines. 2002.
  • Yagiz S, Karahan H. Application of various optimization techniques and comparison of their performances for predicting TBM penetration rate in rock mass. Int J Rock Mech Min Sci. 2015;80:308–315.
  • Copur C. A set of indices based on indentation tests for assessment of rock cutting performance and rock properties. J South Afr Inst Miner Metall. 2003;103:589–599.
  • Yagiz S, Gokceoglu C. Application of fuzzy inference system and nonlinear regression models for predicting rock brittleness. Expert Syst Appl. 2010;37:2265–2272.
  • Altindag R. Reply to the discussion by yagiz on “assessment of some brittleness indexes in rock-drilling efficiency” by Altindag, rock mechanics and rock engineering. Rock Mech Rock Eng. 2010;43:375–376.
  • Altindag R. Assessment of some brittleness indexes in rock-drilling efficiency. Rock Mech Rock Eng. 2010;43:361–370.
  • Yagiz S. Discussion on “assessment of some brittleness indexes in rock-drilling efficiency” by Rasit Altindag, rock mechanics and rock engineering. Rock Mech Rock Eng. 2010;43:371–373.
  • Yagiz S. Assessment of brittleness using rock strength and density with punch penetration test. Tunnelling Underground Space Technol. 2009;24:66–74.
  • Yarali O, Kahraman S. The drillability assessment of rocks using the different brittleness values. Tunnelling Underground Space Technol. 2011;26:406–414.
  • Yilmaz G. A new methodology for the analysis of the relationship between rock brittleness index and drag pick cutting efficiency. J South Afr Inst Miner Metall. 2005;105:727–733.
  • Göktan RM. Brittleness and micro-scale rock cutting efficiency. Min Sci Technol. 1991;13:237–241.
  • Gong QM, Zhao J. Influence of rock brittleness on TBM penetration rate in Singapore granite. Tunnelling Underground Space Technol. 2007;22:317–324.
  • Denkhaus HG. Brittleness and drillability. J S Afr Inst Min Metall. 2003;102:61–66.
  • Altindag R. Reply to HG Denkhaus’ Brittleness and drillability’in the Journal of the SAIMM, vol 103. no. 8. pp. 523. J South Afr Inst Miner Metall. 2003;103:525.
  • Honda H, Sanada Y. Hardness of coal. Fuel. 1956;35:451–461.
  • Morley A. Strength of material; 1944. n.d. Longmans.
  • Hucka V, Das B. Brittleness determination of rocks by different methods. Int J Rock Mech Min Sci Geomech Abstr. 1974;11(Elsevier):389–392.
  • Altindag R. The role of rock brittleness on analysis of percussive drilling performance. Proc. 5th Natl. Rock Mech. Symp.; 2000; Turkey; p. 105–112.
  • Yarali O, Soyer E. The effect of mechanical rock properties and brittleness on drillability. Sci Res Essays. 2011;6:1077–1088.
  • Nejati HR, Moosavi SA. A new brittleness index for estimation of rock fracture toughness. J Min Environ. 2017;8:83–91.
  • Yilmaz NG, Karaca Z, Goktan RM, et al. Relative brittleness characterization of some selected granitic building stones: influence of mineral grain size. Constr Build Mater. 2009;23:370–375.
  • Lawn BR, Marshall DB. Hardness, toughness, and brittleness: an indentation analysis. J Am Ceram Soc. 1979;62:347–350.
  • Meng F, Zhou H, Zhang C, et al. Evaluation methodology of brittleness of rock based on post-peak stress–strain curves. Rock Mech Rock Eng. 2015;48:1787–1805.
  • Kaunda RB, Asbury B. Prediction of rock brittleness using nondestructive methods for hard rock tunneling. J Rock Mech Geotech Eng. 2016;8:533–540.
  • Koopialipoor M, Fallah A, Armaghani DJ, et al. Three hybrid intelligent models in estimating flyrock distance resulting from blasting. Eng Comput. 2018. DOI:10.1007/s00366-018-0596-4
  • Koopialipoor M, Armaghani DJ, Haghighi M, et al. A neuro-genetic predictive model to approximate overbreak induced by drilling and blasting operation in tunnels. Bull Eng Geol Environ. 2017. DOI:10.1007/s10064-017-1116-2
  • Hasanipanah M, Armaghani DJ, Amnieh HB, et al. A risk-based technique to analyze flyrock results through rock engineering system. Geotechnol Geol Eng. n.d.;36:2247–2260.
  • Koopialipoor M, Armaghani DJ, Hedayat A, et al. Applying various hybrid intelligent systems to evaluate and predict slope stability under static and dynamic conditions. Soft Comput. 2018. DOI:10.1007/s00500-018-3253-3
  • Ghaleini EN, Koopialipoor M, Momenzadeh M, et al. A combination of artificial bee colony and neural network for approximating the safety factor of retaining walls. Eng Comput. 2018;35:1–12.
  • Zhou J, Aghili N, Ghaleini EN, et al. A Monte Carlo simulation approach for effective assessment of flyrock based on intelligent system of neural network. Eng Comput. 2019. DOI:10.1007/s00366-019-00726-z
  • Zhao Y, Noorbakhsh A, Koopialipoor M, et al. A new methodology for optimization and prediction of rate of penetration during drilling operations. Eng Comput. 2019. DOI:10.1007/s00366-019-00715-2
  • Jian Z, Shi X, Huang R, et al. Feasibility of stochastic gradient boosting approach for predicting rockburst damage in burst-prone mines. Trans Nonferrous Met Soc China. 2016;26:1938–1945.
  • Wang M, Shi X, Zhou J, et al. Multi-planar detection optimization algorithm for the interval charging structure of large-diameter longhole blasting design based on rock fragmentation aspects. Eng Optim. 2018;50:2177–2191.
  • Wang M, Shi X, Zhou J. Charge design scheme optimization for ring blasting based on the developed Scaled Heelan model. Int J Rock Mech Min Sci. 2018;110:199–209.
  • Yang X-S Firefly algorithm, Levy flights and global optimization. In: Research and development in intelligent systems XXVI. London: Springer; 2010. p. 209–218.
  • Talbi E-G. Metaheuristics: from design to implementation. Vol. 74. John Wiley & Sons; 2009.
  • Yang X-S. Firefly algorithms for multimodal optimization. Int. Symp. Stoch. algorithms; Berlin (Heidelberg): Springer; 2009. p. 169–178.
  • McCulloch WS, Pitts W. A logical calculus of the ideas immanent in nervous activity. Bull Math Biophys. 1943;5:115–133.
  • Ch S, Mathur S. Particle swarm optimization trained neural network for aquifer parameter estimation. KSCE J Civ Eng. 2012;16:298–307.
  • Koopialipoor M, Ghaleini EN, Haghighi M, et al. Overbreak prediction and optimization in tunnel using neural network and bee colony techniques. Eng Comput. 2018. DOI:10.1007/s00366-018-0658-7
  • Gordan B, Koopialipoor M, Clementking A, et al. Estimating and optimizing safety factors of retaining wall through neural network and bee colony techniques. Eng Comput. 2018. DOI:10.1007/s00366-018-0642-2
  • Mohandes MA. Modeling global solar radiation using Particle Swarm Optimization (PSO). Sol Energy. 2012;86:3137–3145.
  • Ahmadi MA, Shadizadeh SR. New approach for prediction of asphaltene precipitation due to natural depletion by using evolutionary algorithm concept. Fuel. 2012;102:716–723.
  • Armaghani DJ, Hasanipanah M, Mohamad ET. A combination of the ICA-ANN model to predict air-overpressure resulting from blasting. Eng Comput. 2016;32:155–171.
  • Haykin S. Neural networks. Upper Saddle River (NJ): Prentice Hall; 1999.
  • Priddy KL, Keller PE. Artificial neural networks: an introduction. Vol. 68. SPIE press; 2005.
  • Armaghani DJ, Mohamad ET, Hajihassani M, et al. Application of several non-linear prediction tools for estimating uniaxial compressive strength of granitic rocks and comparison of their performances. Eng Comput. 2016;32:189–206.
  • Yang X-S. Firefly algorithm, stochastic test functions and design optimisation. Int J Bio-Inspired Comput. 2010;2:78–84.
  • Kwiecień J, Filipowicz B. Firefly algorithm in optimization of queueing systems. Bull Polish Acad Sci Tech Sci. 2012;60:363–368.
  • Alweshah M. Firefly algorithm with artificial neural network for time series problems. Res J Appl Sci Eng Technol. 2014;7:3978–3982.
  • Balachennaiah P, Suryakalavathi M, Nagendra P. Optimizing real power loss and voltage stability limit of a large transmission network using firefly algorithm. Eng Sci Technol Int J. 2016;19:800–810.
  • Long NC, Meesad P, Unger H. A highly accurate firefly based algorithm for heart disease prediction. Expert Syst Appl. 2015;42:8221–8231.
  • Rajan A, Malakar T. Optimal reactive power dispatch using hybrid Nelder–mead simplex based firefly algorithm. Int J Electr Power Energy Syst. 2015;66:9–24.
  • Koopialipoor M, Fahimifar A, Ghaleini EN, et al. Development of a new hybrid ANN for solving a geotechnical problem related to tunnel boring machine performance. Eng Comput. 2019. DOI:10.1007/s00366-019-00701-8
  • Hornik K, Stinchcombe M, White H. Multilayer feedforward networks are universal approximators. Neural Networks. 1989;2:359–366.
  • Hecht-Nielsen R Kolmogorov’s mapping neural network existence theorem. Proc. Int. Conf. Neural Networks, vol. 3, New York (NY): IEEE Press; 1987. p. 11–13.
  • Ripley BD. Statistical aspects of neural networks. Networks Chaos—Stat Probab Asp. 1993;50:40–123.
  • Paola JD. Neural network classification of multispectral imagery. Master Tezi. The University of Arizona, USA; 1994.
  • Wang C. A theory of generalization in learning machines with neural network applications. 1994.
  • Masters T. Practical neural network recipes in C++. Morgan Kaufmann; 1993.
  • Kaastra I, Boyd M. Designing a neural network for forecasting financial and economic time series. Neurocomputing. 1996;10:215–236.
  • Kanellopoulos I, Wilkinson GG. Strategies and best practice for neural network image classification. Int J Remote Sens. 1997;18:711–725.
  • Zorlu K, Gokceoglu C, Ocakoglu F, et al. Prediction of uniaxial compressive strength of sandstones using petrography-based models. Eng Geol. 2008;96:141–158.
  • Koopialipoor M, Murlidhar BR, Hedayat A, et al. The use of new intelligent techniques in designing retaining walls. Eng Comput. 2019. DOI:10.1007/s00366-018-00700-1
  • Liao X, Khandelwal M, Yang H, et al. Effects of a proper feature selection on prediction and optimization of drilling rate using intelligent techniques. Eng Comput. 2019. DOI:10.1007/s00366-019-00711-6
  • Koopialipoor M, Ghaleini EN, Tootoonchi H, et al. Developing a new intelligent technique to predict overbreak in tunnels using an artificial bee colony-based ANN. Environ Earth Sci. 2019;78:165.

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