Chemical thermodynamics analysis for in-situ gasification chemical looping combustion of lignite with phosphogypsum for syngas

•The product of syngas mainly came from 〈CaSO4+4C→CaS+4CO〉 solid-solid reaction and 〈C+H2O(g)→CO+H2〉 gas-solid reaction.•Lower heating value (LHV) and cold gas efficiency were higher than 55000.00kJ/Nm3 and 63.00%, respectively.•Optimizing operation conditions were obtained using Factsage 6.4.•Theor...

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Bibliographic Details
Published in:Applied thermal engineering 2017-02, Vol.112, p.516-522
Main Authors: Yang, Jie, Ma, Liping, Tang, Jianxiao, Liu, Hongpan, Zhu, Bin, Lian, Yan, Cui, Xiaojing
Format: Article
Language:English
Subjects:
Calorific value
Carbon dioxide
Carbon monoxide
Chemical industry
Cold gas
Cold gas efficiency
Combustion
Fluidized bed combustion
Gas-solid reactions
Gasification
In-situ gasification chemical looping combustion (IG-CLC)
Lignite
Lower heating value (LHV)
Moisture
Phosphogypsum
Phosphoric acid
Raw materials
Studies
Sulfur
Syngas
Synthesis gas
Synthetic fuels
Thermodynamics
Thermodynamics analysis
Water vapor
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Summary:•The product of syngas mainly came from 〈CaSO4+4C→CaS+4CO〉 solid-solid reaction and 〈C+H2O(g)→CO+H2〉 gas-solid reaction.•Lower heating value (LHV) and cold gas efficiency were higher than 55000.00kJ/Nm3 and 63.00%, respectively.•Optimizing operation conditions were obtained using Factsage 6.4.•Theory and experiment showed that PG is an excellent oxygen carrier for syngas production during lignite’s IG-CLC process. Phosphogypsum (PG) is a by-product of wet phosphoric acid, whereas low rank coal-lignite has high moisture and high-sulfur which seriously influence its direct use. As a promising raw material for chemical industry, syngas can be obtained through a properly designed in-situ gasification chemical looping combustion process (IG-CLC). This concept was demonstrated using a thermodynamic software Factsage, by employing PG as oxygen carrier and lignite as fuel under different conditions. The experiments were conducted in laboratory to confirm the theoretical calculations. The results showed that the product of syngas mainly came from solid-solid reaction and gas-solid reaction. Meanwhile, the optimal conditions for syngas production were found to be: the PG/lignite ratio of about 1; reaction temperatures of over 850°C. In addition, water vapor and carbon dioxide were found to have promotive effect on the syngas output. For PG/lignite ratio of 1 and at 850°C, the values for lower heating value (LHV) and cold gas efficiency were higher than 55000.00kJ/Nm3 and 63.00%, respectively. Compared with lignite combustion at 900°C, the production of CO and hydrogen was significantly high. Moreover, the results showed that PG is a promising oxygen carrier for syngas production by IG-CLC process.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2016.10.106