Coal-direct chemical looping(CDCL) is a promising CO_(2) capture technology with low costs.Potassium modification can significantly enhance the reactivity of iron-based oxygen carriers and coal.However,potassium loss ...Coal-direct chemical looping(CDCL) is a promising CO_(2) capture technology with low costs.Potassium modification can significantly enhance the reactivity of iron-based oxygen carriers and coal.However,potassium loss causes a decline in cyclic stability.To address this,we prepared a potassium hexatitanate-modified iron-based OC and conducted CDCL experiments in a fixed-bed reactor using Zhundong coal coke as fuel.The study examined the impact of potassium hexatitanate on carbon conversion,OC activity stability,and potassium maintenance.Additionally,Fact Sage was used to calculate potassium fugacity patterns at different temperatures,Fe_(2)O_(3)/C molar ratios,and OC reduction degrees.Results showed that potassium hexatitanate increased carbon conversion,achieving 50%conversion at 40% potassium addition.In multi-cycle tests,carbon conversion rose with increased cycle times,reaching 84%.This improvement is attributed to ion exchange between Fe^(3+) and Ti^(4+),which induces lattice distortion and creates oxygen vacancies,enhancing OC reactivity.Potassium content remained stable during multi-cycle tests,indicating the effective potassium retention capacity of potassium hexatitanate.展开更多
基金fnancially supported by the Open Research Fund Program of Anhui Provincial Institute of Modern Coal Processing Technology,Anhui University of Science and Technology (MTY202201)。
文摘Coal-direct chemical looping(CDCL) is a promising CO_(2) capture technology with low costs.Potassium modification can significantly enhance the reactivity of iron-based oxygen carriers and coal.However,potassium loss causes a decline in cyclic stability.To address this,we prepared a potassium hexatitanate-modified iron-based OC and conducted CDCL experiments in a fixed-bed reactor using Zhundong coal coke as fuel.The study examined the impact of potassium hexatitanate on carbon conversion,OC activity stability,and potassium maintenance.Additionally,Fact Sage was used to calculate potassium fugacity patterns at different temperatures,Fe_(2)O_(3)/C molar ratios,and OC reduction degrees.Results showed that potassium hexatitanate increased carbon conversion,achieving 50%conversion at 40% potassium addition.In multi-cycle tests,carbon conversion rose with increased cycle times,reaching 84%.This improvement is attributed to ion exchange between Fe^(3+) and Ti^(4+),which induces lattice distortion and creates oxygen vacancies,enhancing OC reactivity.Potassium content remained stable during multi-cycle tests,indicating the effective potassium retention capacity of potassium hexatitanate.
