Your search keyword '"Fu, Leijie"' showing total 3 results

1. Development of a comprehensive simulation model for H2-rich syngas production by air–steam gasification of biomass.

Author

Fu, Leijie, Cao, Yan, and Bai, Yu

Subjects

*BIOMASS gasification, *SYNTHESIS gas, *SYNTHETIC fuels, *CHEMICAL kinetics, *SIMULATION methods & models, *BIOMASS

Abstract

Gasification is a multiphase process that converts the solid fuels into useful synthetic gas. Despite the potential of biomass gasification as a clean technique to produce a high caloric value syngas, it is not as well looked upon as its advantages suggest. In the present study, an ASPEN plus model of biomass gasification was developed with considering the kinetics of the reactions and tar cracking mechanism. Firstly, the model was validated against the experimental data in the literature. Next, a parametric study was done to investigate and evaluate the performance and produced gas composition of air–steam gasification of biomass. The effect of various operational parameters, such as the reaction temperature, equivalence ratio (ER) and steam/biomass ratio (S/B) on the gas product composition, products yield and the gasifier performance was investigated. The results showed that the increase of reaction temperature not only can enhance the H2 content in the gas stream, but inhibit the formation of tar. The achieved optimal conditions for production of maximum H2 content (16.18 vol %) were as follows: reaction temperature of 800 °C, S/B of 0.8 and ER of 0.211. [ABSTRACT FROM AUTHOR]

Published

2022

2. H2-rich syngas produced from steam gasification of municipal solid waste: a modeling approach.

Author

Fu, Leijie, Cao, Yan, and Du, Jiang

Subjects

SOLID waste, SYNTHESIS gas, ENDOTHERMIC reactions, BIOMASS gasification, STEAM flow, WATER-gas, TAR

Abstract

Steam gasification is considered as a clean route to produce H2-rich syngas and other energy products such as methanol. However, environmental issues and technical problems related to tar formation have become serious challenges in commercialization of biomass gasification. In the present study, an ASPEN plus® model was developed to convert the municipal solid waste (MSW) into a H2-rich syngas in the presence of steam as gasification agent. Different operation conditions, temperatures (750–900 °C) and steam flow rates (SFRs) (0.138–0.312 kg/h) were studied for their effects on the gas compositions, product yields and gasifier performances. The results indicated that the H2 content increased by increasing the gasification temperature. When the temperature was raised from 750 to 900 ℃, the gas yield rose by 29.8% due to the enhanced endothermic reactions. Furthermore, with the increase in gasification temperature, the tar yield declined with respect to the tar cracking reaction. The addition of steam significantly improved H2 production by simultaneously promoting the water–gas shift reaction and tar cracking reactions. To summarize, the present model provided positive predictions of the MSW gasification in terms of tar elimination and H2-rich syngas production. [ABSTRACT FROM AUTHOR]

Published

2022

3. Combined-gasification of biomass and municipal solid waste in a fluidized bed gasifier.

Author

Cao, Yan, Fu, Leijie, and Mofrad, Amir

Subjects

BIOMASS gasification, FLUIDIZED bed gasifiers, SOLID waste, COAL gas, FOSSIL fuels

Abstract

Due to the environmental problems associated with burning of fossil fuels and population growth, more attention has been paid to develop renewable energies in recent years. Among all options for renewable energy utilization, biomass gasification is more popular because of environmental benefits and economic issues. In the present study, a series of experiments were carried out to study the influence of blending ratio, reaction temperature, equivalence ratio (ER) on co-gasification characteristics of pine sawdust (SD) and municipal solid waste (MSW). By increasing the blending ratio from 100% SD to 100% MSW, CO and CH 4 respectively increased from 16.7 to 18.8 vol% and from 4.1 to 5.1 vol%, while an opposite trend was found for H 2 and CO 2. Over the ranges of the experimental conditions used, the tar content and gas yield varied from 5.4 to 10.1 g/Nm3 and 1.34 to 1.15 Nm3/kg, respectively. • Experimental analysis of co-gasification of biomass and MSW was performed. • Effect of key operating parameters on gas quality and tar content was studied. • HHV of producer gas was increased by increasing of blending ratio. [ABSTRACT FROM AUTHOR]

Published

2019