Biofiltration of hydrogen sulfide by Sulfolobus metallicus at high temperatures

Biofiltration of reduced sulfur compounds such as hydrogen sulfide has been mainly applied to emissions at mild temperatures (25 to 35 °C). However, an important number of industrial gaseous emission containing sulfur compounds, from diverse industrial sectors (petroleum refinery, cellulose producti...

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Bibliographic Details
Published in:Water science and technology 2012-01, Vol.66 (9), p.1958-1961
Main Authors: Morales, M, Silva, J, Morales, P, Gentina, J C, Aroca, G
Format: Article
Language:English
Subjects:
Biofilters
Biofiltration
Bioreactors - microbiology
Capacity
Cellulose
Emissions
Filtration - methods
Food industry
Food plants
High temperature
Hot Temperature
Hydrogen sulfide
Hydrogen Sulfide - chemistry
Hydrogen Sulfide - metabolism
Hydrogen sulphide
Industrial emissions
Industrial plants
Industry
Inoculation
Load distribution
Loading rate
Petroleum
Petroleum industry
Refineries
Removal
Residence time
Smelting
Sulfolobus - metabolism
Sulfolobus metallicus
Sulfur
Sulfur compounds
Sulfur removal
Sulphides
Sulphur
Trickling filters
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Summary:Biofiltration of reduced sulfur compounds such as hydrogen sulfide has been mainly applied to emissions at mild temperatures (25 to 35 °C). However, an important number of industrial gaseous emission containing sulfur compounds, from diverse industrial sectors (petroleum refinery, cellulose production, smelting, rendering plants and food industries) are emitted at temperatures over 50 °C. Most of the studies on thermophilic systems report that a higher elimination capacity can be obtained at elevated temperature, allowing the design of smaller equipment for the same loading rate than that required for removing the same load under mesophilic conditions. A biotrickling filter inoculated with Sulfolobus metallicus, which operates at three different residence times, 60, 80 and 120 s, and two different temperatures (45 and 55 °C) for treating H(2)S is reported. The input loads of H(2)S were progressively increased from 0 to 100 gS/m(3). The aim of this study was to determine the capacity and ability of S. metallicus to oxidize H(2)S at high temperatures. The better removal capacity of H(2)S obtained was 37.1 ± 1.7 gS/m(3) h at 55 °C for a residence time of 120 s. The difference of the removal capacity of H(2)S between the two temperatures was 4 g/m(3) h on average of sulfur removal for the different residence times.
ISSN:0273-1223
1996-9732
DOI:10.2166/wst.2012.402