Integration of biomass drying with combustion/gasification technologies and minimization of emissions of organic compounds

Svoboda, Karel, Martinec, Jiří, Pohořelý, Michael and Baxter, David Integration of biomass drying with combustion/gasification technologies and minimization of emissions of organic compounds Chemical Papers, Vol.63, No. 1, 2009, 15-25

Document type: Článok z časopisu / Journal Article
Collection: Chemical papers  

Author(s) Svoboda, Karel
Martinec, Jiří
Pohořelý, Michael
Baxter, David
Title Integration of biomass drying with combustion/gasification technologies and minimization of emissions of organic compounds
Journal name Chemical Papers
Publication date 2009
Year available 2009
Volume number 63
Issue number 1
ISSN 0366-6352
Start page 15
End page 25
Place of publication Poland
Publisher Versita
Collection year 2009
Language english
Subject 270000 Biological Sciences
270100 Biochemistry and Cell Biology
Abstract/Summary Moisture content (MC) of green biomass or raw biomass materials (wood, bark, plants, etc.) commonly exceeds 50 mass % (wet basis). The maximum possible MC of biomass fuel for big scale combustion (e.g. fluidized bed combustion with low external heat losses) is approximately 60–65 mass %. Higher biomass MC generally causes operational problems of biomass combustors, lower stability of burning and higher CO and VOC emissions. Gasification of biomass with higher MC produces fuel gas of lower effective heating values and higher tar concentrations. In this review, various technological schemes for wood drying in combination with combustion/gasification with the assessment of factors for possible minimization of emissions of organics from the drying processes are compared. The simple direct flue gas biomass drying technologies lead to exhaust drying gases containing high VOC emissions (terpenes, alcohols, organic acids, etc.). VOC emissions depend on the drying temperature, residence time and final MC of the dried biomass. Indirect biomass drying has an advantage in the possibility of reaching very low emissions of organic compounds from the drying process. Exhaust drying gases can be simply destroyed as a part of the total combustion air (gas) in a combustion chamber or a gasifier. Liquid, condensed effluents have to be treated properly because they have relatively high content of organic compounds, some of them accompanied by odor. Drying of biomass with superheated steam offers more uniform drying of both small and bigger particles and shorter periods of higher temperatures of the dried biomass, particularly if drying to the final MC below 15 mass % is required. In practical modern drying technologies, biomass (mainly wood) is dried in recirculated gas of relatively high humidity (approaching saturation) and the period of constant rate drying is longer. Drying of moist wood material (saw dust, chips, etc.) is required in wood pellet production. Emissions of organics in drying depend on biomass properties, content of resins, storing time and on operational aspects of the drying process: drying temperature, drying medium, final MC, residence time, and particle size distribution of the dried biomass (wood). Integration of biomass drying with combustion/gasification processes includes the choice of the drying medium (flue gas, air, superheated steam). Properties of the drying media and operational parameters are strongly dependent on local conditions, fuel input of the combustion/gasification unit, cleaning of the exhaust drying media (gas, steam, wastewater), and on environmental factors and requirements.
 
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