Synergetic conversion laws of biomass and iron ore for syngas and direct reduced iron co-production

This work describes a system for the co-production of syngas and direct reduced iron (DRI) though the synergetic conversion of biomass and iron ore. Iron ore served as the oxygen carrier and catalyst for biomass gasification, while pine sawdust (biomass) served as the reducing agent for iron ore met...

Full description

Saved in:
Bibliographic Details
Published in:Journal of cleaner production 2022-08, Vol.363, p.132387, Article 132387
Main Authors: Yi, Lingyun, Zhang, Nan, Hao, Haowen, Wang, Lin, Xiao, Huarong, Li, Guanghui, Liang, Zhikai, Huang, Zhucheng, Jiang, Tao
Format: Article
Language:English
Subjects:
Biomass gasification
Conversion pathway
Direct reduced iron
Iron ore reduction
Synergetic mechanism
Syngas
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This work describes a system for the co-production of syngas and direct reduced iron (DRI) though the synergetic conversion of biomass and iron ore. Iron ore served as the oxygen carrier and catalyst for biomass gasification, while pine sawdust (biomass) served as the reducing agent for iron ore metallization during this reciprocal conversion process. The effects of conversion temperature, biomass to iron ore ratio and calcination time were investigated. A maximum syngas yield of 72.6% (valid gasification ratio for H and C were 68.8% and 72.7%, respectively) was obtained when biomass was gasified with iron ore (mol ratio C/Fe = 0.8) at 1000 °C for 30 min. DRI with a metallization ratio (MR) of 93.8% was produced concomitantly. The lattice oxygen and catalytic properties of iron ore promoted (i) the conversion of tar and char components into syngas and (ii) the cracking of hydrocarbons into CO and H2. Volatiles derived from biomass enhanced iron ore metallization by accelerating the reduction rate, and bio-char ensured a high MR of the final DRI. The conversion pathway for this was also elucidated. Volatiles and ∼35% of the char reacted with iron ore in the first 10 min to produce all of the H2 in the final syngas and some of the CO. The remaining 65% of the char was gasified in the next 20 min to generate the rest of the CO. The lattice oxygen of iron ore played the key role in early gasification, and the fresh metallic iron played a key role in the subsequent catalysis. This co-conversion approach described herein has potential applications in green fuel gasification or DRI processes. [Display omitted] •Syngas coupling with DRI production via a synergetic conversion was developed.•Iron ore promoted the conversion of tar/char and cracking of hydrocarbons as well.•Lattice oxygen chiefly acted on early gasification and then catalysis of iron.•Volatiles boosted metallization process and char ensured the final MR of iron ore.•Conversion pathway of biomass and iron ore in this process has been figured out.
ISSN:0959-6526
1879-1786
DOI:10.1016/j.jclepro.2022.132387