374
Views
10
CrossRef citations to date
0
Altmetric
Original Articles

Characteristics Analysis of Post-Explosion Coal Dust Samples by X-ray Diffraction

, , , , &
Pages 740-754 | Received 19 Dec 2016, Accepted 16 Nov 2017, Published online: 12 Dec 2017

References

  • Abbasi, T., and Abbasi, S.A. 2007. Dust explosions cases, causes, consequences, and control. J. Hazard. Mater., 140(1–2), 7–44.
  • Abuswer, M., Amyotte, P., Khan, F., and Morrison, L. 2014s An optimal level of dust explosion risk management: framework and application. J. Loss Prev. Process Ind., 26(6),1530–1541.
  • Amyotte, P.R., and Eckhoff, R.K. 2010. Dust explosion causation, prevention and mitigation: An overview. J. Chem. Health Saf., 17(1),15–28.
  • Amyotte P.R., and Kenneth, M. 1993. The ignitability of coal dust-air and methane-coal dust air mixtures. Fuel, 72, 671–679.
  • Amyotte, P.R., Pegg, M.J., and Khan, F.I. 2009. Application of inherent safety principles to dust explosion prevention and mitigation. Process Saf. Environ. Prot., 87(1), 35–39.
  • Attiq, G., Amyotte, P.R., and Khan, F.I. 2004. An inherent safety-based incident investigation methodology. Process Saf. Prog., 23(3), 197–205.
  • Bai, H.L., Pan, J.N., and Zhao, Y.Q. 2013. XRD study on brittle deformation coal of different metamorphism degree. Saf. Coal Mines, 44(11), 12–14.
  • Candra, K.J., Pulung, S.A., and Sadashiv, M.A. 2014. Dust dispersion and management in underground mining faces. Int. J. Min. Sci. Technol., 24(1), 39–44.
  • Carpenter, A.M., Niksa, S., and Scott, D.H. 2005. Effects of coal ash on combustion systems. IEA Clean Coal Center, London, United Kingdom.
  • Cashdollar, K.L. 1996. Coal dust explosibility. J. Loss Prev. Process Ind., 9(1), 65–76.
  • Cashdollar, K.L. 2000. Overview of dust explosibility characteristics. J. Loss Prev. Process Ind., 13(3–5), 183–199.
  • Chen, Y.D. 2012. The thermal decomposition behavior of dolomite and application. Doctoral dissertation. Jilin University, Changchun, China.
  • Dong, Q., Zhang, H., and Zhu, Z. 2015. Evolution of structure properties during Zhundong coal pyrolysis. Procedia Eng., 102, 4–13.
  • Fan, W.T, Lu, J.Z, and Shen, B.H 2007. Coal Mine Disaster Control Technology and Countermeasures, China University of Mining and Technology Press, Xuzhou, China.
  • Gieras, M., Klemens, R., Rarata, G., and Wolański, P. 2006. Determination of explosion parameters of methane-air mixtures in the chamber of 40 d m3, at normal and elevated temperature. J. Loss Prev. Process Ind., 19(2), 263–270.
  • Going, J.E., Chatrathi, K., and Cashdollar, K.L. 2000. Flammability limit measurements for dusts in 20-l and 1-m3 vessels. J. Loss Prev. Process Ind., 13(3–5), 209–219.
  • Hattingh, B.B., Everson, R.C., Neomagus, H.W.J.P., and Bunt, J.R. 2011. Assessing the catalytic effect of coal ash constituents on the CO2, gasification rate of high ash, South African coal. Fuel Process. Technol., 92(10), 2048–2054.
  • He, X.Q 2011. Theory and Technology of Coal Mine Disaster Prevention and Control in China, China University of Mining and Technology Press, Xuzhou, China.
  • Hu, C.X., Bai, J.F., and Xue, Z.H. 2016. Influence research of turbulence intensity on threshold and on-coming flow velocity of coal-dust particle. J. China Univ. Min. Technol., 45(1),189–194.
  • Ji, Y., Ren, T., Wynne, P., Wan, Z., Ma, Z., and Wang, Z. 2016. A comparative study of dust control practices in Chinese and Australian longwall coal mines. Int. J. Min. Sci. Technol., 26(2), 199–208.
  • Jiang, C.H. 2014. The Technique and Application of Polycrystalline X-Ray Diffraction, Chemical Industry Press, Beijing, China.
  • Lai, C.F., Duan, Z.H., Zhang, Y.F., and Zhang, L.L. 2010. Explosion mechanism of carbon powder. Explos. Shock Waves, 30(3), 325–328.
  • Langford, J.I. 2010. X-ray diffraction procedures for polycrystalline and amorphous materials. J. Appl. Crystallogr., 8(5), 573–574.
  • Li, J.X. 2009. X-ray diffraction Rietveld refinement method quantitative phase analysis minerals in coals Guizhou province. Doctoral dissertation, Henan Polytechnic University.
  • Li, Q., Lin, B., Dai, H., and Zhao, S. 2012. Explosion characteristics of H₂/CH₄/air and CH₄/coal dust/air mixtures. Powder Technol, 229, 222–228.
  • Li, Q.Z., Zhai, C., Wu, H.J., Lin, B.Q., and Zhu, C.J. 2011. Investigation on coal dust explosion characteristics using 20L explosion sphere vessels. J. China Coal Soc., S1, 119–124.
  • Li, X., Li, Z., Wang, E., Feng, J., Chen, L., Li, N., Kong, X.G. 2016. Extraction of microseismic waveforms characteristics prior to rock burst using Hilbert–Huang transform. Measurement, 91, 101–113.
  • Liang, J.K. 2011. Determination of Crystal Structure by Powder Diffraction Method, The Science Publishing Company, Beijing, China.
  • Liu, G.J., Wang, J.X., Yang, P.Y., and Peng, Z.C. 2003. Minerals in coal and their changes during combustion. J. Fuel Chem. Technol, 31(3), 215–219.
  • Liu, Y., Gupta, R., Sharma, A., Wall, T., Butcher, A., Miller, G., Gottlieb, P., French, D. 2005. Mineral matter–organic matter association characterisation by qemscan and applications in coal utilisation. Fuel, 84(10), 1259–1267.
  • Liu, Z., Lin, S., Zhang, S., Wang, E., and Liu, G. 2016. Observations of microscopic characteristics of post-explosion coal dust samples. J. Loss Prev. Process Ind., 43, 378–384.
  • Liu, Z., Zhang, S., Guo, R., Geng, L., Zhang, Y., and Lin, S. 2015a. Comparative analysis for explosion characteristics of coal dust with different metamorphic grades. Saf. Coal Mines, 46(4): 170–173.
  • Liu, Z., Zhang, S., Zhonghui, L.I., Zhao, E., Song, L., and Guo, R. 2015b. Investigation on coal dust explosion residues using 20l explosion sphere vessels. J. China Univ. Min. Technol, 44(5), 823–828.
  • Liu, Z.T. 2010. Experimental study on characteristic parameters of material evidences in gas (coal dust) explosion. Doctoral dissertation. Chinese University of Mining and Technology, Xuzhou, China.
  • Liu, Z.T., Hong, S., and Zhang, S.S. 2017. Experimental investigations on explosion behaviors of large-particle and formation rules of gas residues. J. Loss Prev. Process Ind., 46(2017),37–44.
  • Lu, L., Kong, C., Sahajwalla, V., and Harris, D. 2002. Char structural ordering during pyrolysis and combustion and its influence on char reactivity. Fuel, 81(9), 1215–1225.
  • Lu, L., Sahajwalla, V., Kong, C., and Harris, D. 2001. Quantitative x-ray diffraction analysis and its application to various coals. Carbon, 39(12), 1821–1833.
  • Luo, Y.F., and Wen-Hua, L.I. 2004. X-ray diffraction analysis on the different macerals of several low-to-medium metamorphic grade coals. J. China Coal Soc, 29(3): 338–341.
  • Machado, A.D.S., Mexias, A.S., Vilela, A.C.F., and Osorio, E. 2013. Study of coal, char and coke fines structures and their proportions in the off-gas blast furnace samples by x-ray diffraction. Fuel, 114(4), 224–228.
  • Medina, C. H., Maccoitir, B., Sattar, H., Slatter, D. J. F., Phylaktou, H. N., & Andrews, G. E. 2015. Comparison of the explosion characteristics and flame speeds of pulverised coals and biomass in the ISO standard 1 m3, dust explosion equipment. Fuel, 151(1), 91–101.
  • National Energy Administration of China. 2016. The development of coal industry in the “13th Five-Year” plan. National Energy Administration of China.
  • Qin, Y., Han, Q., Zhao, Z., Du, Z., Feng, J., Li, W.Y., Vaassile, S.V., Vassileva, C.G. 2017. Impact of biomass addition on organic structure and mineral matter of char during coal-biomass co-gasification under CO2 atmosphere. Fuel, 202, 556–562.
  • Qiu, S.X. 2015.Study on minerals phase transformation in coal coking and coke gasification process. Doctoral dissertation Chongqing University, Chongqing, China.
  • Reinmöller, M., Schreiner, M., Guhl, S., Neuroth, M., and Meyer, B. 2017. Formation and transformation of mineral phases in various fuels studied by different ashing methods. Fuel, 202(2), 641–649.
  • Sahajwalla, V., Kong, C., and Harris, D. 2001. Quantitative X-ray diffraction analysis and its application to various coals. Carbon, 39(12), 1821–1833.
  • Sahajwalla V, Gupta SK, Al-Omari Y, Saha-Chaudhury N, et al. Combustion characteristics of pulverized coals and char released in blast furnace off-gas. In: 62nd Ironmaking conference proceedings. ISS Warrendale, USA; 2003. p. 775–785.
  • Seames, W.S. 2003. An initial study of the fine fragmentation fly ash particle mode generated during pulverized coal combustion. Fuel Process. Technol., 81(2), 109–125.
  • Shirazi, A.R., Börtin, O., Eklund, L., and Lindqvist, O. 1995. The impact of mineral matter in coal on its combustion, and a new approach to the determination of the calorific value of coal. Fuel, 74(2), 247–251.
  • State Administration of Coal Mine Safety (SACMS). 2016. Summary of Coal Mine Safety Production in 2015, State Administration of Coal Mine Safety, Beijing, China.
  • Takagi, H., Maruyama, K., Yoshizawa, N., Yamada, Y., and Sato, Y. 2004. XRD analysis of carbon stacking structure in coal during heat treatment. Fuel, 83(17–18), 2427–2433.
  • Warren, B.E. 1941. X-ray diffraction in random layer lattices. Phys. Rev., 59(9), 693–698.
  • Wilson, S.A., Raudsepp, M., and Dipple, G.M. 2009. Quantifying carbon fixation in trace minerals from processed kimberlite: A comparative study of quantitative methods using X-ray powder diffraction data with applications to the Diavik Diamond Mine, Northwest Territories, Canada. Appl. Geochem., 25(2), 321–322.
  • Wu, K., Ding, R., Han, Q., Yang, S., Wei, S., and Ni, B. 2010. Research on unconsumed fine coke and pulverized coal of bf dust under different PCI rates in BF at Capital Steel Co. ISIJ Int., 50(3), 390–395.
  • Yuan, Z., Khakzad, N., Khan, F., and Amyotte, P. 2015. Dust explosions: A threat to the process industries. Process Saf. Environ. Prot., 98, 57–71.
  • Zhang, K.N., Deng, J., and Yang, H. 2014s. Experimental study of the characteristic features of the microstructure of coal at different coal sorts. J. Saf. Environ., 4, 67–71.
  • Zhang, L., Li, Z., Yang, Y., Zhou, Y., Kong, B., Li, J., Li, J.H., Si, L.L. 2016. Effect of acid treatment on the characteristics and structures of high-sulfur bituminous coal. Fuel, 184, 418–429.
  • Zhang, L.C., Liu, L.P., and Xu, J.D. 2014b. Research on experiment test systems of mechanism of fame propagation for gas and coal dust explosion. J. North China Inst. Sci. Technol., 4, 19–24.
  • Zhang, X., Wang, J., Liu, Q., Te, G., Ban, Y., Wang, Y., Li, N., He, R.X., Zhang, Y.S., Zhi, K.D. 2017. The effects of sodium and alkalinity on the microcrystalline structure and the steam gasification performance of Shengli lignite. J. Anal. Appl. Pyrolysis.
  • Zhou, G., Xue, J., and Cheng, W.M. 2015. Effects of stacking structure on the wettability of coal dust based on X-ray diffraction experiment. Chin. J. Eng., 37(12), 1535–1541.
  • Zhu, Y.H., and Wang, Z.H. 2013. Coal Chemistry, Chemical Industry Press, Beijing, China.
  • Zhu, Z., Jia, Z., and Luo, H. 2015. Characteristics of gas explosion flow fields in complex pipelines. Int. J. Min. Sci. Technol., 25(1), 157–164.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.