Journal
ENERGY
Volume 270, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.energy.2023.126904
Keywords
Biomass pyrolysis; Thermal decomposition; CO2 gasification; Gas emission properties
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Introducing CO2 in the pyrolysis medium enhances CO2 sequestration and carbon conversion efficiency. Through experiments, the effects of introducing CO2 on the thermal conversion behaviors of biomass were studied. Results showed that introducing CO2 promoted carbon release and increased total weight loss during gasification. The release of CO, CO2, CH4, and H2 occurred in chronological order with prolonged pyrolysis time. Temperature had negligible effects on CO emissions, and high temperature favored H2 release while inhibiting CO2 emissions. The particle residence time had no significant influence on gas emissions or yields in a CO2-containing atmosphere.
Introducing CO2 in the pyrolysis medium could not only provide a route for CO2 sequestration but also poten-tially increase the carbon conversion efficiency. Herein, to reveal the effects of introducing CO2 in the pyrolysis medium alongside N2 on the thermal conversion behaviours of biomass, a series of pyrolysis/gasification ex-periments with/without CO2 in the pyroysis medium were conducted in a thermogravimetric analyser (TGA) and a self-established fixed-bed experimental system. The effects of reaction temperature, atmosphere and residence time on syngas emissions and compositions were elucidated in details. Introducing CO2 in the pyrolysis agent resulted in an additional consumption of residuals, promoting CO release due to char-CO2 reactions. During gasification, the total weight loss increased with increasing CO2 concentration. As the pyrolysis reaction was prolonged, the release of CO, CO2, CH4, and H2 occurred in chronological order. Reaction temperatures below 600 degrees C had negligible effects on CO emissions. For pyrolysis under N2, the H2 concentration in syngas increased obviously with increasing temperature, while that of CO2 presented the opposite trend, indicating that high temperature favoured H2 release while CO2 emissions could be inhibited. The particle residence time had no obvious influence on either gas emissions or yields in a CO2-containing atmosphere.
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