Characteristics of mass, heat and gaseous products during coal spontaneous combustion using TG/DSC–FTIR technology

DeRosa MI. Analysis of mine fires for all U.S. underground and surface coal mining categories: 1990–1999. Information Circular 9470; 2004. p. 43.

Yuan L, Smith AC. Simulating spontaneous combustion——looking at CFD modeling of spontaneous heating in longwall gob areas. Coal USA Mag.; 2009. 32–3.

Jun D, Zhao J, Xiao Y, Zhang Y, Huang A, Shu C. Thermal analysis of the pyrolysis and oxidation behaviour of 1/3 coking coal. J Therm Anal Calorim. 2017;129:1779–86.

Heffern EL, Coates DA. Geologic history of natural coal-bed fires, Powder River basin, USA. Int J Coal Geol. 2004;59:25–47.

Sheail J. “Burning Bings”: a study of pollution management in mid-twentieth Century Britain. J Hist Geogr. 2005;31:134–48.

Chatterjee RS. Coal fire mapping from satellite thermal IR data—a case example in Jharia Coalfield, Jharkhand, India. ISPRS J Photogramm. 2006;60:113–28.

Yuan L, Smith AC. Numerical study on effects of coal properties on spontaneous heating in longwall gob areas. Fuel. 2008;87:3409–19.

Yang Y, Liu F, Lv X. Analysis of the reason for methane explosion in Chenjiashan Coal Mine. Min Saf Environ Prot. 2007;34:85–7.

Pone JDN, Hein KAA, Stracher GB, Annegarn HJ, Finkleman RB, Blake DR, McCormack JK, Schroeder P. The spontaneous combustion of coal and its by-products in the Witbank and Sasolburg Coalfields of South Africa. Int J Coal Geol. 2007;72:124–40.

Grubb JW. Preventative measures for spontaneous combustion in underground coal mines. Ph.D. dissertation, Colorado School of Mines; 2008. p. 348.

Kim CJ, Sohn CH. A novel method to suppress spontaneous ignition of coal stockpiles in a coal storage yard. Fuel Process Technol. 2012;100:73–83.

Yuan L, Smith AC. The effect of ventilation on spontaneous heating of coal. J Loss Prev Process Ind. 2012;25:131–7.

Smith AC, Yuan L. Simulation of spontaneous heating in longwall gob area with a bleederless ventilation system. Min Eng. 2008;60:61–6.

Wessling S, Kuenzer C, Kessels W, Wuttke WM. Numerical modeling for analyzing thermal surface anomalies induced by underground coal fires. Int J Coal Geol. 2008;74:175–84.

Carras JN, Day SJ, Saghafi A, Williams DJ. Greenhouse gas emissions from low temperature oxidation and spontaneous combustion at open-cut coal mines in Australia. Int J Coal Geol. 2009;78:161–8.

Sahu HB, Padhee S, Mahapatra SS. Prediction of spontaneous heating susceptibility of Indian coals using fuzzy logic and artificial neural network models. Expert Syst Appl. 2011;38:2271–82.

Qi GS, Wang DM, Zheng KM, Xu J, Qi XY, Zhong XX. Kinetics characteristics of coal low-temperature oxidation in oxygen depleted air. J Loss Prev Process Ind. 2015;35:224–31.

Bhoi S, Banerjee T, Mohanty K. Molecular dynamic simulation of spontaneous combustion and pyrolysis of brown coal using ReaxFF. Fuel. 2014;136:326–33.

Kök MV. Recent developments in the application of thermal analysis techniques in fossil fuels. J Therm Anal Calorim. 2008;91:763–73.

Mohalik NK, Panigrahi DC, Singh VK. Application of thermal analysis techniques to assess proneness of coal to spontaneous heating. J Therm Anal Calorim. 2009;98:507–19.

Avila C, Wu T, Lester E. Estimating the spontaneous combustion potential of coals using thermogravimetric analysis. Energy Fuel. 2014;28:1765–73.

Garcia P, Halla PJ, Fanor M. The use of differential scanning calorimetry to identify coals susceptible to spontaneous combustion. Thermochim Acta. 1999;336:41–6.

Baris K, Kizgut S, Didari V. Low-temperature oxidation of some Turkish coals. Fuel. 2012;93:423–32.

Zhang WQ, Jiang SG, Wang K, Wang LY, Xu YL, Wu ZY, Shao H, Wang YH, Miao ML. Thermogravimetric dynamics and FTIR analysis on oxidation properties of low-rank coal at low and moderate temperatures. Int J Coal Prep Util. 2015;35:39–50.

Zhang YL, Wang JF, Wu JM, Xue S, Li ZF, Chang LP. Modes and kinetics of CO2 and CO production from low-temperature oxidation of coal. Int J Coal Geol. 2015;140:1–8.

Jun D, Zhao J, Xiao Y, Huang A, Zhang Y, Wang C, Shu C. Spontaneous combustion in six types of coal by using the simultaneous thermal analysis-Fourier transform infrared spectroscopy technique. J Therm Anal Calorim. 2016;126:1591–602.

Jun D, Li Q, Xiao Y, Wen H. The effect of oxygen concentration on the non-isothermal combustion of coal. Thermochim Acta. 2017;653:106–15.

Wang QS, Guo S, Sun JH. Spontaneous combustion prediction of coal by C80 and ARC techniques. Energy Fuel. 2009;23:4871–6.

He F, Yi WM, Bai XY. Investigation on caloric requirement of biomass pyrolysis using TG–DSC analyzer. Energy Convers Manag. 2006;47:2461–9.

Slovák V, Taraba B. Effect of experimental conditions on parameters derived from TG-DSC measurements of low-temperature oxidation of coal. J Therm Anal Calorim. 2010;101:641–6.

Marinov SP, Gonsalvesh L, Stefanova M, Yperman J, Carleer R, Reggers G, Yurum Y, Groudeva V, Gadjanov P. Combustion behaviour of some biodesulphurized coals assessed by TGA/DTA. Thermochim Acta. 2010;497:46–51.

Mohalik NK, Panigrahi DC, Singh VK. An investigation to optimise the experimental parameters of differential scanning calorimetry method to predict the susceptibility of coal to spontaneous heating. Arch Min Sci. 2010;55:669–89.

Deng J, Zhao J, Huang A, Zhang Y, Wang C, Shu C. Thermal behavior and microcharacterization analysis of second-oxidized coal. J Therm Anal Calorim. 2017;127:439–48.

Xiao Y, Li Q, Deng J, Shu C, Wang W. Experimental study on the corresponding relationship between the index gases and critical temperature for coal spontaneous combustion. J Therm Anal Calorim. 2017;127:1009–17.