My watch list
my.chemeurope.com  
Login  

E-Beam SO2 and NOx removal from flue gases in the presence of fine water droplets

April 2013
Publication year: 2013
Source:Radiation Physics and Chemistry, Volume 85



The Electron Beam Flue Gas Treatment (EBFGT) has been proposed as an efficient method for removal of SO2 and NO x many years ago. However, the industrial application of this procedure is limited to just a few installations. This article analyses the possibility of using medium-power EB accelerators for off-gases purification. By increasing electron energy from 0.7MeV to 1–2MeV it is possible to reduce the energy losses in the windows and in the air gap between them (transformer accelerators can be applied as well in the process). In order to use these mid-energy accelerators it is necessary to reduce their penetration depth through gas and this can be achieved by increasing the density of the reaction medium by means of dispersing a sufficient amount of fine water droplets (FWD). The presence of FWD has a favorable effect on the overall process by increasing the level of liquid phase reactions. A special reactor was designed and built to test the effect of FWD on the treatment of flue gases with a high concentration of SO2 and NO x using high-energy EBs (9MeV). By determining the energy efficiency of the process the favorable effect of using FWD and high-energy EB was demonstrated.
Highlights ► The medium-energy EB accelerators are proposed for flue gases treatment. ► The energy losses in the windows and in the air gap between them are reduced. ► To increase the density of the reaction medium and to reduce the penetration depth of EB fine water droplets (FWD) are used. ► Determining the energy efficiency the favorable effect of the method was demonstrated. ► The maximum amount of FWD was determined from the total energy balance of the process.



Journal:   Radiation Physics and Chemistry
Year:   2013
DOI:   10.1016/j.radphyschem.2012.10.008
Publication date:   18-Mar-2013
Facts, background information, dossiers
More about Elsevier
Your browser is not current. Microsoft Internet Explorer 6.0 does not support some functions on Chemie.DE