Effects of Particle Shrinkage and Devolatilization Models on High-Temperature Biomass Pyrolysis and Gasification

Ku, Xiaoke; Li, Tian; Løvås, Terese

doi:10.1021/acs.energyfuels.5b00953

Cited by 27 publications

(13 citation statements)

References 29 publications

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“…Instead of only studying temperature, Chaos also performed the sensitivity analyses of mass loss rate (MLR) to material properties. Other studies on the sensitivity of the pyrolysis model regarding different parameters had been conducted by researchers in the past as well . In this study, sensitivity analyses were performed on both the surface temperature and the MLR for a charring material to quantify the sensitive of the input properties.…”

Section: Methodsmentioning

confidence: 99%

Methodology for material property determination

et al. 2019

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Summary Predicting solid material pyrolysis requires numerous parameters/properties that are time consuming and difficult to measure. Multiobjective optimization techniques have been used to determine these parameters; however, a methodology for the types of tests needed for the optimization and parameters that should be optimized versus measured has not been fully established. This study investigated combinations of testing protocols and parameters for optimization to determine a testing and optimization methodology that results in the accurate parameters. A Shuffled Complex Evolution (SCE) optimization routine was used to determine parameters based on some parameters being known (ie, measured) and others being determined through optimization and different combinations of types of input data. The results indicate that material testing should be done at three different heating rates in a thermogravimetric analyzer (TGA) and at three different heat fluxes in the cone calorimeter. The TGA tests and two cone calorimeter tests are input into the SCE optimization routine to determine the remaining parameters. The third cone calorimeter test is used to validate the parameters determined using the methodology. The method provides parameters within 20% of the actual parameters input into the Fire Dynamics Simulator (FDS) virtual experiment models. This method is applied to Polymethyl methacrylate (PMMA) experimental data to prove effectiveness.

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Section: Methodsmentioning

confidence: 99%

Methodology for material property determination

et al. 2019

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“…It was found higher temperature leads to lower tar yield. The effects of particle shrinkage were studied by testing two shrinking models in the DPM simulation of biomass pyrolysis in a falling reactor 98 with Scheme A2. The results showed that the constant volume model predicts a faster pyrolysis and longer particle residence time than the constant density model.…”

Section: Reactor-scale Biomass Pyrolysismentioning

confidence: 99%

Overview of Computational Fluid Dynamics Simulation of Reactor-Scale Biomass Pyrolysis

Xiong

Yang

et al. 2017

ACS Sustainable Chem. Eng.

157

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Computational fluid dynamics (CFD) has been widely used in both scientific studies and industrial applications of reactor-scale biomass pyrolysis. In this Perspective, the state-of-the-art progress in CFD modeling of reactor-scale biomass pyrolysis was summarized and discussed. First, because of the importance of biomass pyrolysis reaction kinetics to the predictability of CFD, the commonly used pyrolysis reaction kinetics in CFD modeling of reactor-scale biomass pyrolysis were reviewed. The characteristics of each reaction kinetics were described. Then, the theoretical basis and practical applications of three main CFD modeling approaches, i.e., porous media model, multifluid model, and discrete particle model for simulating reactor-scale biomass pyrolysis were presented. The activities and progresses with respect to each CFD modeling approach for reactor-scale biomass pyrolysis were reviewed. Aspects such as experimental validation, modeling speed, and capability were discussed. Finally, the paper was concluded with comments on future directions in CFD modeling of reactor-scale biomass pyrolysis.

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“…As mentioned before, the particle shrinkage should be considered in the modeling of conversions of solid fuels. A pair of shrinkage models were most commonly adopted in previous numerical studies: , namely, the constant size model and constant density model. Other shrinkage patterns were also proposed or employed by researchers. , Among different particle shrinkage models, the model proposed by Di Blasi gives a comprehensive description of the particle shrinkage for biomass pyrolysis process.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Computational Fluid Dynamics/Discrete Element Method Investigation on the Biomass Fast Pyrolysis: The Influences of Shrinkage Patterns and Operating Parameters

Luo

Wang

et al. 2018

Ind. Eng. Chem. Res.

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In this study, we present a computational fluid dynamics/discrete element method (CFD-DEM) framework for biomass fast pyrolysis. With model validations against experiments, the effects of the particle shrinkage and superficial gas velocity on the pyrolysis process in the fluidized bed reactor are investigated. The results show that the shrinkage pattern has minor effect on the product yields, but it greatly affects the entrainment behaviors. It is found that the constant density shrinkage pattern leads to the longest residence time, and the constant size shrinkage pattern results in the shortest residence time. Interestingly, the time that biomass particles stay in the dense region shows a reverse trend. It is demonstrated that the gas velocity has a minor effect on the heat-transfer rate and chemical conversion rate of biomass particles, but it has a profound impact on the distributions of solid concentration and heterogeneous reactions.

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Effects of Particle Shrinkage and Devolatilization Models on High-Temperature Biomass Pyrolysis and Gasification

Cited by 27 publications

References 29 publications

Methodology for material property determination

Methodology for material property determination

Overview of Computational Fluid Dynamics Simulation of Reactor-Scale Biomass Pyrolysis

Computational Fluid Dynamics/Discrete Element Method Investigation on the Biomass Fast Pyrolysis: The Influences of Shrinkage Patterns and Operating Parameters

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