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Simultaneous in-situ measurements of gas temperature and pyrolysis of biomass smoldering via X-ray computed tomography
Authors:Emeric Boigné  N. Robert Bennett  Adam Wang  Khadijeh Mohri  Matthias Ihme
Affiliation:1. Department of Mechanical Engineering, Stanford University, Stanford, CA 94305, United States;2. Department of Radiology, Stanford University, Stanford, CA 94305, United States;3. Institute for Combustion and Gas Dynamics, University of Duisburg-Essen, Duisburg 47057, Germany
Abstract:In-situ X-ray computed tomography (XCT) imaging is employed to investigate the smoldering dynamics of biomass at the sub-millimeter scale. This technique provides simultaneous and spatially-resolved information about the gas temperature and the biomass density, thereby enabling tracking of the pyrolysis and char oxidation fronts. To achieve well-controlled heating and flow conditioning, oak biomass samples are instrumented above a diffusion flame inside a tube, with total oxygen concentrations of 6% and 11% per volume. Experiments are performed on a laboratory XCT system. The flow is diluted with Kr to increase X-ray attenuation in the gas phase thus allowing for simultaneous 3D measurements of sample density and surrounding temperature. XCT scans are acquired every 90 s at a spatial resolution of 135 µm. The high spatial resolution enables the volumetric visualization of the smoldering process that is associated with pyrolysis and char oxidation. These measurements show how the grain structure affects flame stabilization and induces fingering of the pyrolysis front, while crack formation accelerates the char oxidation locally. Evaluations of the sample mass via XCT are compared with load cell measurements, showing good agreement. A low-order model is developed to evaluate the propagation speeds of pyrolysis and oxidation fronts from the X-ray data over time, and comparisons are made with the surface recess speed.
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