• Title of article

    Modeling of aerosol formation during biomass combustion for various furnace and boiler types

  • Author/Authors

    Thomas and Jِller، نويسنده , , Markus and Brunner، نويسنده , , Thomas and Obernberger، نويسنده , , Ingwald، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2007
  • Pages
    12
  • From page
    1136
  • To page
    1147
  • Abstract
    In the frame of the EU-financed project BIOASH an existing model for simulating aerosol formation during combustion was improved and adapted for biomass combustion systems in order to contribute to a better understanding of aerosol formation and behavior and to the solution of ash-related problems in biomass furnaces and boilers. Subsequently, the model was applied for several test cases (test runs performed within the BIOASH project) in order to compare and evaluate modeling and measurement results. del is a plug flow model considering gas phase modeling by means of thermodynamic equilibrium calculations and a kinetic approach for modeling gaseous sulfate formation. The main particle formation mechanisms nucleation, condensation and agglomeration as well as particle precipitation mechanisms (diffusion, thermophoresis, turbophoresis, inertial impaction and gravitational settling) as well as the condensation of ash forming vapors on boiler walls are considered. s of modeling aerosol formation in different kinds of combustion units were compared with results from measurements regarding PSD and chemical composition of the aerosol particles at boiler outlet. The modeling results show a good match with the experimental results, which indicates the good applicability of the model. Moreover, the different properties of the aerosol particles regarding PSD and chemical composition due to different combustion and boiler technologies and different biomass fuels, which result in different formation pathways, become obvious.
  • Keywords
    Biomass combustion , aerosols , MODELING , Ash formation
  • Journal title
    Fuel Processing Technology
  • Serial Year
    2007
  • Journal title
    Fuel Processing Technology
  • Record number

    1506646