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J Air Waste Manag Assoc

Title:		Thermophilic Toluene Biofiltration
Author(s):		Matteau Y; Ramsay B;
Address:		"a Department of Chemical Engineering , Ecole Polytechique de Montreal , Montreal , Canada"
Journal Title:		J Air Waste Manag Assoc
Year:		1999
Volume:		49
Issue:		3
Page Number:		350 - 354
DOI:		10.1080/10473289.1999.10463808
ISSN/ISBN:		2162-2906 (Electronic) 1096-2247 (Linking)
Abstract:		"Thermophilic biodegradation of toluene with active compost biofilters was studied. Thermophilic conditions were maintained either by daily substrate addition (semicontinuous composting) or with a heating system (batch thermophilic composting). The semicontinuous system was designed for the treatment of cool (less than approximately 35 degrees C) gases under thermophilic conditions, while the extended batch approach was developed for the treatment of warmer gases. When the semicontinuous system was operated at 50 degrees C (after a one-day start-up period) at an average inlet concentration of 5.5 g m(-3), toluene was degraded at a rate ranging from 73 to 110 g C m(-3) hr(-1). Batch thermophilic treatment was somewhat less effective at the same inlet concentration. Semicontinuous toluene biofiltration at 60 degrees C was also investigated, but biodegradation rates were significantly lower than at 50 degrees C. In all systems, toluene biodegradation was proportional to the inlet concentration. Rates of up to 289 g C m(-3) hr(-1) (at an inlet concentration of 14.7 g m(-3)) were achieved for semicontinuous and batch operation and 251 g C m(-3) hr(-1) (at an inlet concentration of 18.4 g m(-3)) for batch thermophilic at 50 degrees C. Semicontinuous thermophilic operation at 60 degrees C showed a maximum rate of 119 g C m(-3) hr(-1). Active compost ther-mophilic biofiltration was found to be very effective when concentrations are high. At lower concentrations, rates were similar to those obtained with mesophilic biofiltration. Mixing, humidity, and the presence of cosubstrate were important parameters in maintaining high degradation rates. Biofiltration in the batch thermophilic mode could be useful when conventional biofiltration is ineffective due to elevated gas temperatures. Biofiltration in the semicontinuous thermophilic could reduce the biofilter size necessary for treatment of cooler gases containing high concentrations of volatile organic compounds"
Keywords:
Notes:		"PubMed-not-MEDLINEMatteau, Yanick Ramsay, Bruce eng 1999/03/01 J Air Waste Manag Assoc. 1999 Mar; 49(3):350-354. doi: 10.1080/10473289.1999.10463808"