Computationally efficient coarse-graining XDEM/CFD modeling of fixed-bed combustion of biomass
2022 (English)In: Combustion and Flame, ISSN 0010-2180, E-ISSN 1556-2921, Vol. 238, article id 111876Article in journal (Refereed) Published
Abstract [en]
In the multi-scale modeling of a dense particle system, the particle phase and the gas phase can be modeled on vastly different scales. The coupling between the two models has a critical influence on the predictions obtained from the combined framework but can be accomplished in a variety of ways under different assumptions. In this work, a transient 3D model using a new coupling approach for fixed-bed combustion of biomass is presented. The developed model is formulated as an Eulerian-Lagrangian framework. A particle grid, generated based on the fluid grid, is applied as a transfer grid, and a diffusion operation is implemented to smooth the interactions between the gas phase and the particles. The interactions between gas and solid phases as well as the radiative heat transfer between particles are considered. The particle motion is resolved by the soft-sphere model, whereas the conversion is calculated based on a thermally thick particle model. All sub-models are optimized to enhance computational efficiency. The 3D model is validated by comparing the simulations with laboratory-scale experiments for a fixed-bed operated in counter-current combustion mode. The key simulation parameters are configured by sensitivity analysis. The simulation results are in good agreement with the experimental measurements, and the combustion regimes with different air inlet conditions are well captured. The coupling effects are discussed in detail. The particle grid size influences the prediction of the transient results, and the interplay between the heat transfer mechanisms inside the fixed-bed and the coupling scheme is thoroughly analyzed. Both inter-particle radiation and gas-to-particle convection play essential roles in the heat transfer inside the fuel bed, while the inter-particle heat conduction can be neglected. © 2021 The Authors
Place, publisher, year, edition, pages
Elsevier Inc. , 2022. Vol. 238, article id 111876
Keywords [en]
Biomass, CFD, Coupling, Fixed-bed combustion, 3D modeling, Combustion, Computational fluid dynamics, Gases, Heat conduction, Particle size analysis, Sensitivity analysis, 3D models, 3d-modeling, CFD modeling, Coarse Graining, Computationally efficient, Dense particle systems, Fixed bed, Gas-phases, Multiscale modeling, Computational efficiency, article, diffusion, heat transfer, motion, particle radiation, prediction, simulation, solid, thermodynamics
National Category
Energy Engineering
Identifiers
URN: urn:nbn:se:ri:diva-57490DOI: 10.1016/j.combustflame.2021.111876Scopus ID: 2-s2.0-85121153771OAI: oai:DiVA.org:ri-57490DiVA, id: diva2:1623759
Note
Funding details: Vattenfall; Funding details: Norges Teknisk-Naturvitenskapelige Universitet, NTNU; Funding details: Norges Forskningsråd; Funding text 1: The authors acknowledge the financial support by the Knowledge-Building Project GrateCFD (267957), which is funded by LOGE AB, Statkraft Varme AS, EGE Oslo, Vattenfall AB , Hitachi Zosen Inova AG and Returkraft AS together with the Research Council of Norway through the ENERGIX program. UNINET Sigma2 and NTNU HPC Group provided high-performance computational resources for CFD simulations. Henrik Ström gratefully acknowledges co-financing from the Centre for Combustion Science and Technology (CECOST) and the Swedish Gasification Centre (SFC).; Funding text 2: The authors acknowledge the financial support by the Knowledge-Building Project GrateCFD (267957), which is funded by LOGE AB, Statkraft Varme AS, EGE Oslo, Vattenfall AB, Hitachi Zosen Inova AG and Returkraft AS together with the Research Council of Norway through the ENERGIX program. UNINET Sigma2 and NTNU HPC Group provided high-performance computational resources for CFD simulations. Henrik Str?m gratefully acknowledges co-financing from the Centre for Combustion Science and Technology (CECOST) and the Swedish Gasification Centre (SFC).
2021-12-302021-12-302023-06-08Bibliographically approved