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Effects of pH, CO 2 , and flow pattern on the autotrophic degradation of hydrogen sulfide in a biotrickling filter
Author(s) -
Jin Yaomin,
Veiga María C.,
Kennes Christian
Publication year - 2005
Publication title -
biotechnology and bioengineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.136
H-Index - 189
eISSN - 1097-0290
pISSN - 0006-3592
DOI - 10.1002/bit.20607
Subject(s) - autotroph , hydrogen sulfide , trickling filter , chemistry , sulfur , biomass (ecology) , flue gas desulfurization , sulfate , environmental chemistry , degradation (telecommunications) , sulfide , bioreactor , biodegradation , pulp and paper industry , environmental engineering , sewage treatment , environmental science , organic chemistry , ecology , genetics , telecommunications , bacteria , computer science , engineering , biology
In this study, the effects of pH, CO 2 , and flow pattern on the performance of a biotrickling filter (BTF) packed with plastic Pall rings and treating a H 2 S‐polluted waste gas were investigated to establish the optimum operating conditions and design criteria. The CO 2 concentration had no effect on the biodegradation at H 2 S concentrations below 50 ppm. In the range of 50–127 ppm H 2 S, CO 2 concentrations between 865 and 1,087 ppm enhanced H 2 S removal, while higher concentrations of 1,309–4,009 ppm CO 2 slightly inhibited H 2 S removal. The co‐current flow BTF presented the advantage of a more uniform H 2 S removal and biomass growth in each section than the counter‐current flow BTF. Examination of the pH‐effect in the range of pH 2.00–7.00 revealed optimal activity for autotrophs at pH 6.00. Under optimal conditions, the elimination capacity reached 31.12 g H 2 S/m 3 /h with a removal efficiency exceeding 97%. In the present research, autotrophic biomass was developed in the BTF, performing both a partial oxidization of H 2 S to elemental sulfur and a complete oxidization to sulfate, which is favorable from an environmental point of view. Results showed that around 60% of the sulfide concentration fed to the reactor was transformed into sulfate. Such autotrophic trickling filters may present other advantages, including the fact that they do not release any CO 2 to the atmosphere. Besides, the limited growth of autotrophs avoids potential clogging problems. Experimental performance data were compared with data from a mathematical model. Comparisons showed that the theoretical model was successful in predicting the performance of the biotrickling filter. Copyright © 2005 Wiley Periodicals, Inc.