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Combustion Science and Technology Volume 35, 1983 - Issue 1-4
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Original Articles

Effect of Coal Moisture on Burnout and Nitrogen Oxide Formation

Blaine W. Asay Combustion Laboratory, Chemical Engineering Department, Brigham Young University, Provo, Utah, USA
,
L. Dcuglas Lahjaily Combustion Laboratory, Chemical Engineering Department, Brigham Young University, Provo, Utah, USA
&
Paul O. Hedman Combustion Laboratory, Chemical Engineering Department, Brigham Young University, Provo, Utah, USA
Pages 15-31 | Received 06 Dec 1987, Accepted 01 Apr 1983, Published online: 09 Jun 2010

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Z. Q. Li, Z. C. Chen, R. Sun & S. H. Wu. (2007) New low NOx, low grade coal fired swirl stabilised technology. Journal of the Energy Institute 80:3, pages 123-130.
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J. P. SPINTI, D. W. PERSHING, J. BROUWER & M. P. HEAP. (1997) Influence of Near Burner Combustion Modifications on NOx Formation from an All-Axial Multifuel Burner. Combustion Science and Technology 126:1-6, pages 1-21.
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S. GODOY, M. A. HASSAN, M. A. ISMAIL & F. C. LOCKWOOD. (1991) Measurements of Char Burnout in a Large Scale Laboratory Combustor. Combustion Science and Technology 80:1-3, pages 137-150.
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S. G. GODOY, M. ISMAIL & F. C. LOCKWOOD. (1989) Measurements in a Cylindrical Pulverized Coal Furnace. Influence of Swirl Number on Combustion Performance. Combustion Science and Technology 67:1-3, pages 59-72.
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S. Godoy, K. A. Hirji & F. C. Lockwood. (1988) Combustion Measurements in a Pulverised Coal-Fired Furnace. Combustion Science and Technology 59:1-3, pages 165-182.
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Zixiang Li & Zhengqing Miao. (2020) Effects of moisture and its input form on coal combustion process and NOx transformation characteristics in lignite boiler. Fuel 266, pages 116970.
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Rubén Pérez-Jeldres, Mauricio Flores, Pablo Cornejo, Alfredo Gordon & Ximena García. (2018) Co-firing of coal/biomass blends in a pilot plant facility: A comparative study between Opuntia ficus-indica and Pinus radiata. Energy 145, pages 1-16.
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Jing Wang, Kailiang Zheng, Ravinder Singh, Helen Lou, Jiangping Hao, Baofeng Wang & Fangqin Cheng. (2017) Numerical simulation and cold experimental research of a low-NOx combustion technology for pulverized low-volatile coal. Applied Thermal Engineering 114, pages 498-510.
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Seok-Gi Ahn, Jung-Woo Kim, Gyu-Bo Kim, Si-Hyun Lee & Chung-Hwan Jeon. (2016) Study on the Unburned Carbon and NOx emission of High Moisture Coal. Journal of Energy Engineering 25:4, pages 53-61.
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Qiulin Wang, Jialing Zhu, Tailu Li & Guowei Zhang. (2014) Evaluation of the Integrated Characteristics on Combustion and Drying Using Element Analysis. Energy & Fuels 28:7, pages 4421-4430.
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Jianping Jing, Chunming Zhang, Wei Sun, Jieruo An, Jinsheng Bi & Zhengqi Li. (2013) Influence of mass-flow ratio of inner to outer secondary air on gas–particle flow near a swirl burner. Particuology 11:5, pages 540-548.
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Ming Liu, JunJie Yan, DaoTong Chong, JiPing Liu & JinShi Wang. (2013) Thermodynamic analysis of pre-drying methods for pre-dried lignite-fired power plant. Energy 49, pages 107-118.
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Sung Su Kim, Youn Suk Kang, Hyun Dong Lee, Jae Kwan Kim & Sung Chang Hong. (2012) Release of potassium and sodium species during combustion of various rank coals, biomass, sludge and peats. Journal of Industrial and Engineering Chemistry 18:6, pages 2199-2203.
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Zhichao Chen, Zhengqi Li, Qunyi Zhu, Lianjie Yang & Lizhe Chen. (2011) Concentrator performance within a centrally fuel-rich primary air burner: Influence of multiple levels. Energy 36:7, pages 4041-4047.
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Yon mo Sung, Cheor eon Moon, Jong ryul Kim, Sung chul Kim, Tea hyung Kim, Sang il Seo, Gyung min Choi & Duck jool Kim. (2011) Influence of pulverized coal properties on heat release region in turbulent jet pulverized coal flames. Experimental Thermal and Fluid Science 35:4, pages 694-699.
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Jianping Jing, Zhengqi Li, Lin Wang, Lizhe Chen & Guohua Yang. (2011) Influence of secondary air mass flow rates on gas/particle flow characteristics near the swirl burner region. Energy 36:5, pages 3599-3605.
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Zhichao Chen, Zhengqi Li, Qunyi Zhu & Jianping Jing. (2011) Gas/particle flow and combustion characteristics and NOx emissions of a new swirl coal burner. Energy 36:2, pages 709-723.
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Weidong Fan, Zhengchun Lin, Youyi Li & Yu Li. (2010) Effect of Temperature on NO Release during the Combustion of Coals with Different Ranks. Energy & Fuels 24:3, pages 1573-1583.
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Byoung-Hwa Lee, Ju-Hun Song, Cheon-Sung Lee, Young-June Chang & Chung-Hwan Jeon. (2009) Effect of Coal Properties on Combustion Characteristics in a Pulverized Coal Fired Furnace. Transactions of the Korean Society of Mechanical Engineers B 33:10, pages 737-747.
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Zhichao Chen, Zhengqi Li, Jianping Jing, Lizhe Chen, Shaohua Wu & Yang Yao. (2009) Gas/particle flow characteristics of two swirl burners. Energy Conversion and Management 50:5, pages 1180-1191.
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Zhichao Chen, Zhengqi Li, Jianping Jing, Fuqiang Wang, Lizhe Chen & Shaohua Wu. (2008) The influence of fuel bias in the primary air duct on the gas/particle flow characteristics near the swirl burner region. Fuel Processing Technology 89:10, pages 958-965.
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Zhichao Chen, Zhengqi Li, Fuqiang Wang, Jianping Jing, Lizhe Chen & Shaohua Wu. (2008) Gas/particle flow characteristics of a centrally fuel rich swirl coal combustion burner. Fuel 87:10-11, pages 2102-2110.
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Li Zhengqi, Sun Rui, Chen Lizhe, Wan Zhixin, Wu Shaohua & Qin Yukun. (2002) Effect of primary air flow types on particle distributions in the near swirl burner region. Fuel 81:6, pages 829-835.
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K.R Cliffe & S Patumsawad. (2001) Co-combustion of waste from olive oil production with coal in a fluidised bed. Waste Management 21:1, pages 49-53.
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S.C Hill & L Douglas Smoot. (2000) Modeling of nitrogen oxides formation and destruction in combustion systems. Progress in Energy and Combustion Science 26:4-6, pages 417-458.
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R.P. van der Lans, P. Glarborg & K. Dam-Johansen. (1997) Influence of process parameters on nitrogen oxide formation in pulverized coal burners. Progress in Energy and Combustion Science 23:4, pages 349-377.
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M. Costa, P. Costen, F.C. Lockwood & T. Mahmud. (1991) Detailed measurements in and modelling of an industry-type pulverised-coal flame. Symposium (International) on Combustion 23:1, pages 973-980.
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Philip J. Smith, William A. Sowa & Paul O. Hedman. (1990) Furnace design using comprehensive combustion models. Combustion and Flame 79:2, pages 111-121.
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P. J. Smith, L. D. Smoot & S. C. Hill. (2004) Effects of swirling flow on nitrogen oxide concentration in pulverized coal combustors. AIChE Journal 32:11, pages 1917-1919.
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Douglas C. Rawlins, Geoffrey J. Germane, Paul O. Hedman & L.Douglas Smoot. (1986) Laboratory-scale combustion of coal-water mixtures. Combustion and Flame 63:1-2, pages 59-72.
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Wayne F. Wells, Stephen K. Kramer, L. Douglas Smoot & Angus U. Blackham. (1985) Reactivity and combustion of coal chars. Symposium (International) on Combustion 20:1, pages 1539-1546.
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Scott C. Hill, L. Douglas Smoot & Philip J. Smith. (1985) Prediction of nitrogen oxide formation in turbulent coal flames. Symposium (International) on Combustion 20:1, pages 1391-1400.
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L. Douglas Smoot. (1984) Modeling of coal-combustion processes. Progress in Energy and Combustion Science 10:2, pages 229-267.
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L.Douglas Smoot, Paul O. Hedman & Philip J. Smith. (1984) Pulverized-coal combustion research at Brigham Young University. Progress in Energy and Combustion Science 10:4, pages 359-441.
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