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Original Articles

Free Radical and Functional Group Reaction and Index Gas CO Emission during Coal Spontaneous Combustion

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Pages 834-848 | Received 23 Aug 2017, Accepted 03 Dec 2017, Published online: 18 Dec 2017

References

  • Bandara, T.S., Kannangara, G.S.K., Wilson, M.A., Boreham, C.J., and Fisher, K. 2005. The study of Australian coal maturity: Relationship between solid-state NMR aromaticities and organic free-radical count. Energy Fuels, 19(3), 954–959.
  • Dindarloo, S.R., Hood, M.M., Bagherieh, A., and Hower, J.C. 2015. A statistical assessment of carbon monoxide emissions from the Truman Shepherd coal fire, Floyd County, Kentucky. Int. J. Coal Geol., 144, 88–97.
  • Fittipaldi, M., Gatteschi, D., and Fornasiero, P. 2013. The power of EPR techniques in revealing active sites in heterogeneous photocatalysis: The case of anion doped TiO2. Catal. Today, 206, 2–11.
  • Green, U., Aizenshtat, Z., Ruthstein, S., and Cohen, H. 2012. Stable radicals formation in coals undergoing weathering: Effect of coal rank. Phys. Chem. Chem. Phys., 14(37), 13046–13052.
  • Ham, B. 2005. A review of spontaneous combustion incidents. Presented at the 6th Australasian Coal Operators’ Conference, Brisbane, Queensland, Australia, April 26- 28.
  • Kam, A.Y., Hixson, A.N., and Perlmutter, D.D. 1976a. The oxidation of bituminous coal—I Development of a mathematical model. Chem. Eng. Sci., 31(9), 815–819.
  • Kam, A.Y., Hixson, A.N., and Perlmutter, D.D. 1976b. The oxidation of bituminous coal—II Experimental kinetics and interpretation. Chem. Eng. Sci., 31(9), 821–834.
  • Li, Z.H. 1996. Mechanism of free radical reactions in spontaneous combustion of coal. J. Chin. Univ. Min. Technol., 25(3), 111–114 (in Chinese).
  • Li, Z.H., Kong, B., Wei, A.Z., Yang, Y.L., Zhou, Y.B., and Zhang, L.Z. 2016. Free radical reaction characteristics of coal low-temperature oxidation and its inhibition method. Environ. Sci. Pollut. Res., 23(23), 23593–23605.
  • Liu, J.X., Jiang, X.M., Han, X.X., Shen, J., and Zhang, H. 2014a. Chemical properties of superfine pulverized coals. Part 2. Demineralization effects on free radical characteristics. Fuel, 115, 685–696.
  • Liu, J.X., Jiang, X.M., Shen, J., and Zhang, H. 2014b. Chemical properties of superfine pulverized coal particles. Part 1. Electron paramagnetic resonance analysis of free radical characteristics. Adv. Powder Technol., 25(3), 916–925.
  • Liu, L., and Zhou, F.B. 2010. A comprehensive hazard evaluation system for spontaneous combustion of coal in underground mining. Int. J. Coal Geol., 82, 27–36.
  • Lu, P., Liao, G., Sun, J.H., and Li, P.D. 2004. Experimental research on index gas of the coal spontaneous at low-temperature stage. J. Loss Prev. Process Ind., 17(3), 243–247.
  • Lu, W., Cao, Y.J., and Tien, J.C. 2017. Method for prevention and control of spontaneous combustion of coal seam and its application in mining field. Int. J. Min. Sci. Technol., 27(5), 839–846.
  • Mei, G.D., and Lu, L. 2007. Study on gas forecasting indexes of coal spontaneous combustion based on grey correlative analysis. Presented at the International Conference on Mine Hazards Prevention and Control, Qingdao,Shandong, October 17.
  • Mendham, F., Cliff, D., and Horberry, T. 2014. Is carbon monoxide sensing an effective early fire detection option for underground coal mines? Presented at the Australian Coal Operators’ Conference 2014, Wollongong, NSW, Australia, February 12–14.
  • Niu, H.Y., Deng, X.L., Li, S.L., Cai, K.X., Zhu, H., Li, F., and Deng, J. 2016. Experiment study of optimization on prediction index gases of coal spontaneous combustion. J. Cent. South. Univ., 23(9), 2321–2328.
  • Qi, X.Y., Wang, D.M., Xin, H.H., and Qi, G.S. 2014. An in situ testing method for analyzing the changes of active groups in coal oxidation at low temperatures. Spectrosc. Lett., 47(7), 495–503.
  • Ren, X.W., Wang, F.Z., Guo, Q., Zuo, Z.B., and Fang, Q.S. 2015. Application of foam-gel technique to control CO exposure generated during spontaneous combustion of coal in coal mines. J. Occup. Environ. Hyg., 12(11), D239–D245.
  • Tang, Y.B. 2015. Sources of underground CO: Crushing and ambient temperature oxidation of coal. J. Loss Prev. Process Ind., 38, 50–57.
  • Tian, L.W., Koshland, C.P., Yano. J.K., Yachandra, V.K., Yu, I.T.S., Lee, S.C., and Lucas, D. 2009. Carbon-centered free radicals in particulate matter emissions from wood and coal combustion. Energy Fuels, 23, 2523–2526.
  • Trevits, M.A., Yuan, L., Smith, A.C., Thimons, E.D., and Goodman, G.V. 2008. The status of mine fire research in the United States. Presented at the 21st World Mining Congress, Krakow, Poland, September 7–11.
  • Tseitlin, M., Eaton, S.S., and Eaton, G.R. 2012. Uncertainty analysis for absorption and first-derivative electron paramagnetic resonance spectra. Concepts Magn. Reson., 40A(6), 295–305.
  • Walker, R., and Mastalerz, M. 2004. Functional group and individual maceral chemistry of high volatile bituminous coals from southern Indiana: Controls on coking. Int. J. Coal Geol., 58(3), 181–191.
  • Wang, D.D., He, R.X., Wang, B., Zhou, H.C., Song, Y.M., Zhi, K.D., Chen, J.M., Li, N., Ban, Y.P., and Liu, Q.S. 2017a. Effects of alkali-oxygen oxidation temperature on the structures and combustion properties of Shengli lignite. Rsc. Adv., 7(32), 19833–19840.
  • Wang, D.M. 2012. The Coal Oxidation Dynamics: Theory and Application, Science Press, Beijing, China.
  • Wang, D.M., Xin, H.H., Qi, X.Y., Dou, G.L., and Zhong, X.X. 2014. Mechanism and relationships of elementary reactions in spontaneous combustion of coal: The coal oxidation kinetics theory and application. J. Chin. Coal Soc., 39(8), 1667–1674.
  • Wang, G., Liu, Q.Q., Yan, G.Q., Sun, L.L., Qu, H.Y., and Han, Q.F. 2017b. Control system of spontaneous combustion in coal gangue dumps—A case study at Yuquan Coal Mine in China. Teh. Vjesn., 24(1), 291–300.
  • Wang, G.H., and Zhou, A.N. 2012. Time evolution of coal structure during low temperature air oxidation. Int. J. Min. Sci. Technol., 22(4), 517–521.
  • Wang, H., Dlugogorski, B.Z., and Kennedy, E.M. 2003. Analysis of the mechanism of the low-temperature oxidation of coal. Combust. Flame, 134(1–2), 107–117.
  • Wang, Y.M., Wang, W.Z., Shao, Z.L., Wang, D.M., and Shi, G.Q. 2013. Terahertz measurement of indicator gas emission from coal spontaneous combustion at low temperature. Ecol. Chem. Eng. S., 20(4), 709–718.
  • Wei, A.Z., Li, Z.H., and Yang, Y.L. 2006. Experimental verification of the mechanism of free radicals reactions in spontaneous combustion of coal. Presented at the 5th International Symposium on Safety Science and Technology, Changsha, Hunan, October 24–27.
  • Wen, H., Yu, Z.J., Fan, S.X., Zhai, X.W., and Liu, W.Y. 2017. Prediction of spontaneous combustion potential of coal in the gob area using CO extreme concentration: A case study. Combust. Sci. Technol., 189(10), 1713–1727.
  • Xu, T. 2017. Heat effect of the oxygen-containing functional groups in coal during spontaneous combustion processes. Adv. Powder Technol., 28(8), 1841–1848.
  • Zhang, Y.L., Wang, J.F., Xue, S., Wu, J.M., Chang, L.P., and Li, Z.F. 2016. Kinetic study on changes in methyl and methylene groups during low-temperature oxidation of coal via in-situ FTIR. Int. J. Coal Geol., 154–155, 155–164.
  • Zhong, X.X., Wang, D.M., Xu, Y.L., and Xin, H.H. 2010. The variation characteristics of free radicals in coal oxidation. J. Chin. Coal Soc., 35(6), 960–963.
  • Zhou, C.S., Zhang, Y.L., Wang, J.F., Xue, S., Wu, J.M., and Chang, L.P. 2017. Study on the relationship between microscopic functional group and coal mass changes during low-temperature oxidation of coal. Int. J. Coal Geol., 171, 212–222.
  • Zhou, F.B., Shao, H., Li, J.H., Zhang, X., and Shi, B.B. 2010. Experimental research on combustion product formation during coal spontaneous combustion under reduced oxygen concentrations. J. Chin. Univ. Min. Technol., 39(6), 808–812 (in Chinese).

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