Abstract
The pyrolysis of biomass in a fluidized-bed reactor is studied by a combination of a CFD-DEM algorithm and a multistep kinetic scheme, where fluid dynamics, heat and mass transfer, particle collisions, and the detailed thermochemical conversion of biomass are all resolved. The integrated method is validated by experimental results available in literature and a considerable improvement in predicting the pyrolysis product yields is obtained as compared to previous works using a two-fluid model, especially the relative error in the predicted tar yield is reduced by more than 50%. Furthermore, the evolution of light gas, char and tar, as well as the particle conversion, which cannot easily be measured in experiments, are also revealed. Based on the proposed model, the influences of pyrolysis temperature and biomass particle size on the pyrolysis behavior in a fluidized-bed reactor are comprehensively studied. Numerical results show that the new algorithm clearly captures the dependence of char yield on pyrolysis temperature and the influence of heating rate on light gas and tar yields, which is not possible in simulations based on a simplified global pyrolysis model. It is found that, as the temperature rises from 500 to 700 °C, the light gas yield increases from 17% to 25% and char yield decreases from 22% to 14%. In addition, within the tested range of particle sizes (<1 mm), the impact on pyrolysis products from particle size is relatively small compared with that of the operating temperature. The simulations demonstrate the ability of a combined Lagrangian description of biomass particles and a multistep kinetic scheme to improve the prediction accuracy of fluidized-bed pyrolysis.
Highlights
The thermochemical conversion of biomass has become more and more important in the renewable energy industry in recent years, an industry which contributes above 10% of the total power generation nowadays in European countries [1]
To obtain a comprehensive understanding of biomass pyrolysis in fluidized-bed reactors, this paper is aimed at developing a detailed algorithm based on the combination of the Eulerian–Lagrangian approach denoted CFD-DEM and the multistep pyrolysis kinetics, where both the evolution of syngas and tar species as well as the interphase heat/mass transfer can be accurately considered
Compared with the Eulerian–Eulerian method, the predicted steam yield of the Eulerian–Lagrangian method increases from 11% to 14%, while the difference of tar yield with that of experiment is decreased by more than
Summary
The thermochemical conversion of biomass has become more and more important in the renewable energy industry in recent years, an industry which contributes above 10% of the total power generation nowadays in European countries [1]. Among various routes of biomass utilization, fluidized-bed pyrolysis is one of the most promising technologies to produce bio-oil and other high-quality fuels [2,3,4,5]. These fuels can be used for power generation or serve as an alternative to fossil fuels in the transportation sector. Contemporary biomass conversion technology in fluidized-bed reactors include oxy-combustion, chemical looping combustion, Energies 2020, 13, 5358; doi:10.3390/en13205358 www.mdpi.com/journal/energies
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