Mathematical Modeling of Multi-Phenomena Anisotropic Systems: Ejection of Primary Aerosols during the Fast Pyrolysis of Biomass: Article No. 925

Mario Sanchez, Juan Maya, Farid Chejne, Brennan Pecha, Adriana Quinchia-Figueroa

Research output: Contribution to journalArticlepeer-review

Abstract

This study introduces a novel particle model for biomass fast pyrolysis, incorporating an anisotropic cylindrical particle to address mass and energy transport coupled with aerosol ejection, which previous models have overlooked. The main contribution lies in developing a model that considers aerosol generation in anisotropic cylindrical particles for the first time, addressing bubbling dynamics and bursting within the liquid phase. The population balance equation describes bubble dynamics and aerosol formation, capturing phenomena like nucleation, growth, coalescence, and bursting. The model employs the method of moments with bubble volume as an internal variable, substantially reducing computational costs by eliminating dependence on this variable. Results highlight the significant impact of anisotropy and particle size on aerosol ejection: smaller, less elongated particles experience faster heating, quicker conversion, and the increased accumulation of the liquid intermediate phase. Specifically, 1 mm diameter particles yield higher concentrations of metaplast and bio-oil aerosols, exceeding 15%, compared to concentrations below 11% for 3 mm particles. This model provides insights into aerosol structure (volume, surface area), aiding in understanding aerosol reactivity at the reactor scale.
Original languageAmerican English
Number of pages14
JournalMathematics
Volume12
Issue number6
DOIs
StatePublished - 2024

NREL Publication Number

  • NREL/JA-2800-89766

Keywords

  • aerosols
  • biomass
  • liquid intermediate
  • population balance
  • pyrolysis
  • single particle model

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