[1] J. Toraño, S.Torno, M. Menendez, M. Gent, J. Velasco, Models of methane behaviour in auxiliary ventilation of underground coal mining. Int. J. of Coal Geology 80 (1), 35-43 (2009).
[2] J.K. Richmond, G.C. Price, M.J. Sapko, E.M. Kawenski, Historical summary of coal mine explosions in the United States 1959-1981. In: Bureau of Mines Information Circular (IC-8909), (1983).
[3] The Chamber of Mining Engineers of Turkey (TMMOB), The Occupational Accidents Report in Mining, Turkey (2010).
[4] A .M. Wala, B.J. Kim, Simulation of unsteady-state of airflow and methane concentration processes in mine ventilation systems caused by disturbances in main fan operation. In: Mopusset-Jones (Eds.), the Second US Mine Ventilation Symposium, (1985).
[5] J.S. Edwards, T.X. Ren, R. Jozefowicz, Using CFD to solve mine safety and health problems. In: APCOM XXV Conference, Brisbane, (1995).
[6] M.T. Parra, J.M. Villafruela, F. Castro, C. Méndez, Numerical and experimental analysis of different ventilation systems in deep mines. Building and Env. 41 (2), 87-93 (2006).
[7] J.C. Kurnia, A.P. Sasmito, A.S. Mujumdar, Simulation of Methane Dispersion and Innovative Methane Management in Underground Mining Faces. Appl. Mathematical Modelling 38, 3467-3484 (2014).
[8] J.C. Kurnia, A.P. Sasmito, A.S. Mujumdar, Simulation of A Novel Intermittent Ventilation System for Underground Mines. Tunnelling and Underground Space Technology 42, 206-215 (2014).
[9] X. Wang, X. Liu, Y. Sun, J. An, J. Zhang, H. Chen, Construction schedule simulation of a diversion tunnel based on the optimized ventilation time. J. of Hazard Materials 165, 933-943 (2009).
[10] D. Xie, H. Wang, K.J. Kearfott, Z. Liu, S. Mo, Radon dispersion modeling and dose assessment for uranium mine ventilation shaft exhausts under neutral atmospheric stability. J. of Env. Radioactivity 129, 57-62 (2014).
[11] J. Toraño, S. Torno, M. Menendez, M. Gent, Auxiliary ventilation in mining roadways driven with roadheaders: Validated CFD modelling of dust behaviour. Tunnelling Underground Space Technology 26, 201-210 (2011) .
[12] A .M. Wala, J.C. Yingling, J. Zhang, Evaluation of the face ventilation systems for extended cuts with remotely operated mining machines using three-dimensional numerical simulations. In: Metall. and Exploration Annual Meeting Society for Mining, (1998).
[13] S .M. Aminossadati, K. Hooman, Numerical simulation of ventilation air flow in underground mine workings. In: 12th U.S./North American Mine Ventilation Symposium, 253-259 (2008).
[14] M. Branny, Computer simulation of flow of air and methane mixture in the longwall-return crossing zone. Petroleum Journals Online, 1-10 (2007).
[15] N .I. Vlasin, C. Lupu, M. Şuvar, V.M. Pasculescu, S. Arad, Computerised modelling of methane releases exhaust from a retreating logwall face. In: 4th European Conference on Recent Advances in Civil and Mining Engineering (ECCIE’13), 274-277 (2013).
[16] Z .H. Zhang, E.K. Hov, N.D. Deng, J.H. Guo, Study on 3D mine tunnel modelling. In: the International Conference on Environment, Ecosystem and Development (EE D’07), 35-40 (2007).
[17] S .M. Radui, G. Dolea, R. Cretan, Modeling and simulation of coal winning process on the mechanized face. In: 4th European Conference on Recent Advances in Civil and Mining Engineering (ECCIE’13), 30-35 (2013).

[18] J. Cheng, S. Li, F. Zhang, C. Zhao, S. Yang, A. Ghosh, J. of Loss Prevention in the Process Industries 40, 285-297 (2016).
[19] Z . Wang, T. Ren, Y. Cheng, Numerical investigations of methane flow characteristics on a longwall face Part II: Parametric studies. J. of Naturel Gas Science and Engineering 43, 254-267 (2017b).
[20] Z . Wang, T. Ren, Y. Cheng, Numerical investigations of methane flow characteristics on a longwall face Part I: Methane emission and base model results. J. of Naturel Gas Science and Engineering 43, 242-253 (2017a).
[21] Y . Lu, S. Akhtar, A.P. Sasmito, J.C. Kurnia, Prediction of air flow, methane, and coal dust dispersion in a room and pillar mining face. Int. J. of Mining Science and Technology 27, 657-662 (2017).
[22] Q. Zhang, G. Zhou, X. Qian, M. Yuan, Y. Sun, D. Wang, Diffuse pollution characteristics of respirable dust in fully-mechanized mining face under various velocities based on CFD investigation. J. of Cleaner Production 184, 239-250 (2018).
[23] J. Wachowicz, J.M. Laczny, S. Iwaszenko, T. Janoszek, M. Cempa-Balewicz, Modelling of underground coal gasification process using CFD methods. Arch. Min. Sci. 60, 663-676 (2015).
[24] T . Skjold, D. Castellanos, K.L. Olsen, R.K. Eckhoff, Experimental and numerical investigations of constant volume dust and gas explosions in a 3.6-m flame acceleration tube. J. of Loss Prevention in the Process Industries 30, 164-176 (2014).
[25] C.A. Palmer, E. Tuncalı, K.O. Dennen, T.C. Coburn, R.B. Finkelman, Characterization of Turkish coals: a nationwide perspective. Int. J. Coal Geology 60, 85-115 (2004).
[26] S . Toprak, Petrographic properties of major coal seams in Turkey and their formation. Int. J. of Coal Geology 78, 263-275 (2009).
[27] A .E. Karkınlı, T. Kurban, A. Kesikoglu, E. Beşdok, CFD based risk simulations and management on CBS. In: Congress of Geographic Information Systems, Antalya, Turkey (2011). [28] http://www.theatc.org/events/cleanenergy/pdf/TuesdayMorningBallroom2&3/Bicer, accessed: 09.05.2012.
[29] Turkish Hard Coal Enterprises (TT K), Turkish Hard Coal Enterprise general management activities between 2003 and 2009, (2009).
[30] I. Diego, S. Torno, J. Torano, M. Menendez, M. Gant, A practical use of CFD for ventilation of underground works. Tunnelling Underground Space Technology 26, 189-200 (2011).
[31] S . Torno, J. Torano, M. Ulecia, C. Allende, Conventional and numerical models of blasting gas behaviour in auxiliary ventilation of mining headings. Tunnelling Underground Space Technology 34, 73-81 (2013).
[32] Z . Altaç, Modeling Samples with Gambit and Fluent. Depart. of the Mech. Eng. of Eskisehir Osmangazi Univ., Turkey (2005).
[33] A . Konuk, S. Önder, Statistics for Mining Engineers. Depart. of the Mining Eng. of Eskisehir Osmangazi Univ., Turkey (1999).