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Journal of the Air & Waste Management Association Volume 53, 2003 - Issue 4
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Technical Paper

Modeling Sorbent Injection for Mercury Control in Baghouse Filters: I—Model Development and Sensitivity Analysis

Joseph R.V. Flora Department of Civil and Environmental Engineering, University of South Carolina, Columbia, South Carolina, USA
,
Richard A. Hargis National Energy Technology Laboratory, U.S. Department of Energy, Pittsburgh, Pennsylvania, USA
,
William J. O’Dowd National Energy Technology Laboratory, U.S. Department of Energy, Pittsburgh, Pennsylvania, USA
,
Henry W. Pennline National Energy Technology Laboratory, U.S. Department of Energy, Pittsburgh, Pennsylvania, USA
&
Radisav D. Vidic Department of Civil and Environmental Engineering, University of Pittsburgh, Pittsburgh, Pennsylvania, USA
Pages 478-488 | Published online: 22 Feb 2012

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Arunangshu Mukhopadhyay. (2010) Pulse-jet filtration: An effective way to control industrial pollution Part II: Process characterization and evaluation of filter media. Textile Progress 42:1, pages 1-97.
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Articles from other publishers (26)

Shilin Zhao, Kang Sun, Hui Luo, Yuchen Wang, Yanqun Zhu & Zhiqiang Sun. (2023) Numerical simulation on adsorbent injection system for mercury removal from coal-fired flue gas. Advanced Powder Technology 34:10, pages 104172.
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Ao Shen, Yuqing Wang, Runlin Wang, Yufeng Duan, Jun Tao, Xiaobing Gu, Peng Wang & Zhong Xu. (2022) Numerical simulation of sorbent injection into flue gas for mercury removal in Coal-Fired power Plant. Part 1. Model establishment and validation. Fuel 326, pages 124931.
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Cristina Antuña-Nieto, Elena Rodríguez, M. Antonia López-Antón, Roberto García & M. Rosa Martínez-Tarazona. (2020) Mercury adsorption in the gas phase by regenerable Au-loaded activated carbon foams: a kinetic and reaction mechanism study. New Journal of Chemistry 44:28, pages 12009-12018.
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Ahmed Mohsen, Rania Farouq, Hassan A. Farag & Mostapha Salem. (2019) A Study on the Effect of Operating Parameters on the Efficiency of a Mercury Removal Unit from Natural Gas. Civil and Environmental Engineering Reports 29:2, pages 117-155.
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Jianping Yang, Yongchun Zhao, Xin Guo, Hailong Li, Junying Zhang & Chuguang Zheng. (2018) Removal of elemental mercury from flue gas by recyclable CuCl2 modified magnetospheres from fly ash. Part 4. Performance of sorbent injection in an entrained flow reactor system. Fuel 220, pages 403-411.
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Sean C. Garrick & Michael BühlmannSean C. Garrick & Michael Bühlmann. 2018. Modeling of Gas-to-Particle Mass Transfer in Turbulent Flows. Modeling of Gas-to-Particle Mass Transfer in Turbulent Flows 17 35 .
Sean C. Garrick & Michael BühlmannSean C. Garrick & Michael Bühlmann. 2018. Modeling of Gas-to-Particle Mass Transfer in Turbulent Flows. Modeling of Gas-to-Particle Mass Transfer in Turbulent Flows 1 16 .
Huan Liu, Jianping Yang, Chong Tian, Yongchun Zhao & Junying Zhang. (2017) Mercury removal from coal combustion flue gas by modified palygorskite adsorbents. Applied Clay Science 147, pages 36-43.
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Vishnu Sriram, Zhouyang Liu & Joo-Youp Lee. (2017) Modeling of mercuric chloride removal in ductwork and fabric filter by raw activated carbon injection. Fuel 188, pages 223-231.
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Qiang Zhou, Yu-Feng Duan, Shi-Lin Zhao, Chun Zhu, Min She, Jun Zhang & Shuang-Qun Wang. (2015) Modeling and experimental studies of in-duct mercury capture by activated carbon injection in an entrained flow reactor. Fuel Processing Technology 140, pages 304-311.
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A. Fuente-Cuesta, Ir. Diamantopoulou, M. A. Lopez-Anton, M. Diaz-Somoano, M. R. Martínez-Tarazona & G. P. Sakellaropoulos. (2015) Study of Mercury Adsorption by Low-Cost Sorbents Using Kinetic Modeling. Industrial & Engineering Chemistry Research 54:21, pages 5572-5579.
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Wen Du, Libao Yin, Yuqun Zhuo, Qisheng Xu, Liang Zhang & Changhe Chen. (2015) Performance of CuOx–neutral Al2O3 sorbents on mercury removal from simulated coal combustion flue gas. Fuel Processing Technology 131, pages 403-408.
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Xin Li & Joo-Youp Lee. (2013) Modeling of Mercuric Chloride Removal by CuCl 2 -Impregnated Activated Carbon Sorbent in a Fabric Filter . Energy & Fuels 27:12, pages 7654-7663.
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Yanshan Gao, Zhang Zhang, Jingwen Wu, Linhai Duan, Ahmad Umar, Luyi Sun, Zhanhu Guo & Qiang Wang. (2013) A Critical Review on the Heterogeneous Catalytic Oxidation of Elemental Mercury in Flue Gases. Environmental Science & Technology 47:19, pages 10813-10823.
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Yuanjing Zheng, Anker D. Jensen, Christian Windelin & Flemming Jensen. (2012) Review of technologies for mercury removal from flue gas from cement production processes. Progress in Energy and Combustion Science 38:5, pages 599-629.
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Tim C. KeenerKwang-Joong Oh & Sang-Sup Lee. (2012) Mathematical Model of Mercury Capture in the Filter of an Entrained-Flow Reactor System. Adsorption Science & Technology 30:7, pages 593-599.
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Feng Ding, Yongchun Zhao, Liangliang Mi, Hailong Li, Yang Li & Junying Zhang. (2012) Removal of Gas-Phase Elemental Mercury in Flue Gas by Inorganic Chemically Promoted Natural Mineral Sorbents. Industrial & Engineering Chemistry Research 51:7, pages 3039-3047.
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Sang-Sup Lee, Joo-Youp Lee, Soon-Jai Khang & Tim C. Keener. (2009) Modeling of Mercury Oxidation and Adsorption by Cupric Chloride-Impregnated Carbon Sorbents. Industrial & Engineering Chemistry Research 48:19, pages 9049-9053.
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H.K. Choi, S.H. Lee & S.S. Kim. (2009) The effect of activated carbon injection rate on the removal of elemental mercury in a particulate collector with fabric filters. Fuel Processing Technology 90:1, pages 107-112.
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Fabrizio Scala & Herek L. Clack. (2008) Mercury emissions from coal combustion: Modeling and comparison of Hg capture in a fabric filter versus an electrostatic precipitator. Journal of Hazardous Materials 152:2, pages 616-623.
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Shishir P. Sable, Wiebren de Jong & Hartmut Spliethoff. (2007) Combined Homo- and Heterogeneous Model for Mercury Speciation in Pulverized Fuel Combustion Flue Gases. Energy & Fuels 22:1, pages 321-330.
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Joseph E. WilliamsRamesh GoelJoseph R. FloraRadisav Vidic. (2005) Investigating Role of Growing Adsorbent Bed in a Dead-End PAC/UF Process. Journal of Environmental Engineering 131:11, pages 1583-1588.
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William J O'Dowd, Richard A Hargis, Evan J Granite & Henry W Pennline. (2004) Recent advances in mercury removal technology at the National Energy Technology Laboratory. Fuel Processing Technology 85:6-7, pages 533-548.
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Fabrizio Scala. (2004) Modeling Mercury Capture in Coal-Fired Power Plant Flue Gas. Industrial & Engineering Chemistry Research 43:10, pages 2575-2589.
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. (2004) . Journal of the Japan Institute of Energy 83:8, pages 631-632.
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ao shen, Yuqing Wang, Runlin Wang & Yufeng Duan. (2022) Numerical Simulation of Sorbent Injection into Flue Gas for Mercury Removal in Coal-Fired Power Plant. Part 1. Model Establishment and Validation. SSRN Electronic Journal.
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