Page 335 - Air pollution and greenhouse gases from basic concepts to engineering applications for air emission control
P. 335
312 10 Post-combustion Air Emission Control
6. Brown TD, Smith DN, Hargis RA Jr, O’Dowd WJ (1999) Mercury measurement and its
control: what we know, have learned and need to further investigate. J Air Waste Manag
Assoc 49:1469–1473
7. Broer S, Hammer T (2000) Selective catalytic reduction of nitrogen oxides by combining a
non-thermal plasma and a V 2 O 5 -WO 3 /TiO 2 catalyst. Appl Catal B 28:101–111
8. Chen S, Rostam-Adabi M, Chang R (1996) Mercury removal from combustion flue gas by
activated carbon injection: mass transfer effects, vol 41, no 1. The 211th ACS National
Meeting, New Orleans, LA, pp 442–446
9. Cooper CD, Alley FC (2002) Air pollution control—a design approach, 3rd edn. Waveland
Press Inc., Long Grove
10. Couturier MF, Marquis DL, Steward FR (1994) Reactivation of partially-sulphated limestone
particles from a CFB combustor by hydration. Can J Chem Eng 72:91–97
11. Dunn RF, El-Halwagi MM (1994) Selection of optimal VOC-condensation systems. Waste
Manag 14(2):103–113
12. Farthing GH (1998) Mercury emissions control strategies for coal-fired power plants. In:
Presentation to the 23rd international technical conference on coal utilization and fuel systems,
Clearwater, FL, March 1998
13. Flagan RC, Seinfeld JH (1988) Fundamentals of air pollution engineering. Prentice Hall,
Englewood Cliffs
14. Flagan RC, Seinfeld JH (2012) Fundamentals of air pollution engineering, 2nd edn. Dover
Publishing, Englewood Cliffs
15. Granite EJ, Pennline HW, Hargis RA (2000) Novel sorbents for mercury removal from flue
gas. Ind Eng Chem Res 39:1020–1029
16. Javed MT, Irfan N, Gibbs BM (2007) Control of combustion-generated nitrogen oxides by
selective non-catalytic reduction. J Environ Manage 83:251–289
17. Krissmann J, Siddiqi MA, Peters-Gerth P, Ripke M, Lucas K (1998) A study on the
thermodynamic behaviour of mercury in a wet flue gas cleaning process. Ind Eng Chem Res
37(8):3288–3294
18. LaGrega MD, Buckingham PL, Evans J (1994) Hazardous waste management, chapter 12
thermal treatment. McGraw-Hill, New York
19. Lewandowski DA (1999) Design of thermal oxidation systems for volatile organic
compounds. CRC Press LLC, Boca Raton. ISBN 1-56670-410-3
20. Miller SF, Wincek RT, Miller BG, Scaroni AW (1998) Trace elements emissions when firing
pulverised coal in a pilot-scale combustion facility. In: Proceedings of the 23rd international
technical conference on coal utilization and fuel systems, Clearwater, FL, USA, March 1998,
pp 953–964
21. Mukherjee AB, Kääntee U, Zevenhoven R (2001) The effects of switching from coal to
alternative fuels on heavy metals emissions from cement manufacturing. In: The 6th
international conference on the biogeochemistry of trace elements, Guelph, ON, Canada, 29
Jul–2 Aug 2001
22. Navarrete B, Canadas L, Cortes V, Salvador L, Galindo J (1997) Influence of plate spacing
and ash resistivity on the efficiency of electrostatic precipitators. J Electrostat 39:65–81
23. Neumann U (1991) The Wellman Lord process. Sulphur dioxide and nitrogen oxides in
industrial waste gases: emission, legislation and abatement, eurocourses: Chem Environ sci
3:111–137
24. Qi G, Yang RT, Rinaldi FC (2006) Selective catalytic reduction of nitric oxide with hydrogen
over Pd-based catalysts. J Catal 237:381–392
25. Ray TK (2004) Air pollution control in industries—theory, selection and design of air
pollution control equipment vol. 1. TechBooks International, New Delhi
26. Shearer JA, Smith GW, Myles KM, Johnson I (1980) Hydration enhanced sulfation of
limestone and dolomite in the fluidized-bed combustion of coal. J Air Pollut Control Assoc
30:684–688
27. Sun H, Zhang Y, Quan X, Chen S, Qu Z, Zhou Y (2008) Wire-mesh honeycomb catalyst for
selective catalytic reduction of NO x under lean-burn conditions. Catal Today 139:130–134
