AIChE Symposium Series, Volume 91, Issue 309American Institute of Chemical Engineers, 1972 - Chemical engineering |
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Page 24
... loading , and hence the higher the loading , the better . However , the sodium loading is limited by the sorbent's attrition resistance . A series of laboratory tests concluded that sodium loading should not exceed one monolayer ...
... loading , and hence the higher the loading , the better . However , the sodium loading is limited by the sorbent's attrition resistance . A series of laboratory tests concluded that sodium loading should not exceed one monolayer ...
Page 34
... loading ) , and then decreases with increasing loading of CuO in the sorbent . The sorbent CuO - 2 ( 20 wt . % CuO ) with the optimum loading can take more than 20 % of SO3 in the sulphation stage . The copper oxide sorbent reported by ...
... loading ) , and then decreases with increasing loading of CuO in the sorbent . The sorbent CuO - 2 ( 20 wt . % CuO ) with the optimum loading can take more than 20 % of SO3 in the sulphation stage . The copper oxide sorbent reported by ...
Page 35
... loading when CuO loading is larger than 20 wt . % . Effect of SO2 concentration on the sulphation process is illustrated in Figure 7. SO2 sorption amount increases substantially with SO2 concentration . The sulpahtion rates calculated ...
... loading when CuO loading is larger than 20 wt . % . Effect of SO2 concentration on the sulphation process is illustrated in Figure 7. SO2 sorption amount increases substantially with SO2 concentration . The sulpahtion rates calculated ...
Contents
Foreword | 1 |
NOXSO SO₂NO Flue Gas Treatment Process Adsorption Chemistry and Kinetics | 18 |
Sulphation and Regeneration of SolGel Derived Regenerative Sorbents | 32 |
Copyright | |
1 other sections not shown
Common terms and phrases
activated carbons adsorbed adsorption adsorptive capacities alkyl alumina Aluminosiliceous amine amino-functional anisole bed volumes benzoic acid bulk density catalytic cations Chem Chemical chitosan chlorobenzene CO₂ copolymers copolymers functionalized copper oxide copper oxide sorbents CuO loading CVOC cycle dealuminated decrease dual-function efficiently remove fixed-bed flow rate flue gas desulfurization g/cm³ H₂O Haslbeck increases interactions kinetic m²/g materials MCM-41 type methane methanol micropores ml/min molecules Na₂O nitrogen NO₂ NOXSO process parameters penicillin phenol phenoxyacetate pickup polymeric polymeric resins polymers pore volume porosity precursor presorbed pressure process streams properties reactor regeneration curve resin S-VBC samples selectively and efficiently showed shown in Figure Siliceous simulation SO₂ sorption sodium sol-gel sol-gel derived solvent sorbent sorption sorption capacity storage inhibitors sulfur supported copper oxide surface area synthesized Table TCE sorption templating tertiary thermal TR/CA tyrosinase waste minimization XUS resin y-alumina supported zeolites
References to this book
Nanoporous Materials: Science and Engineering G. Q. Lu,George Xiu Song Zhao No preview available - 2004 |