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The behaviour of multiple reaction fronts during iron (III) oxide reduction in a non-steady state packed bed for chemical looping water splitting

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  • Hua, Xiuning
  • Fan, Yiran
  • Wang, Yidi
  • Fu, Tiantian
  • Fowler, G.D.
  • Zhao, Dongmei
  • Wang, Wei

Abstract

Owing to the unclear temporal and spatial variations of axial solid conversion in a packed bed using iron (III) oxide as an oxygen carrier, we directly observe these variations by means of a sub-layer approach. The results indicate that the behaviour of the multiple reaction fronts during iron (III) oxide reduction by CO or H2 within a packed bed for chemical looping water splitting (CLWS) is strongly dependent on the reaction temperature. When the reaction temperature is lower than the merging temperature, three reaction fronts, i.e., Fe2O3-Fe3O4, Fe3O4-Fe0.947O and Fe0.947O-Fe, and three product zones, i.e., Fe3O4, Fe0.947O and Fe, will appear in the packed bed. In contrast, when the reaction temperature is higher than the merging temperature, the Fe2O3-Fe3O4 and Fe3O4-Fe0.947O fronts merge, leading to the disappearance of the Fe3O4 zone. As a result, only the Fe2O3-Fe0.947O and Fe0.947O-Fe fronts, as well as Fe0.947O and Fe zones will appear in the packed bed. These reduction behaviours are verified by two breakthrough curves, one for TTm, from the thermodynamically controlled reduction of iron (III) oxide in the packed bed. The reaction front movement model, which is proposed based on the reduction behaviour, can be used to determine the maximum solid conversion of the reduction step, i.e., the thermodynamic limitation of the reduction step, in the packed bed CLWS. The maximum solid conversion can reach 0.409 for the CO case and 0.554 for the H2 case. The first discovery of both the behaviours of the reaction fronts movement and the thermodynamic limitations of the reduction step standardizes the criteria for both the oxygen carrier evaluation and the optimization of the operating conditions and provides theoretical support for scaling up the packed bed and developing new technology for packed bed CLWS.

Suggested Citation

  • Hua, Xiuning & Fan, Yiran & Wang, Yidi & Fu, Tiantian & Fowler, G.D. & Zhao, Dongmei & Wang, Wei, 2017. "The behaviour of multiple reaction fronts during iron (III) oxide reduction in a non-steady state packed bed for chemical looping water splitting," Applied Energy, Elsevier, vol. 193(C), pages 96-111.
    • Handle: RePEc:eee:appene:v:193:y:2017:i:c:p:96-111
    DOI: 10.1016/j.apenergy.2017.01.036
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    as
    1. Stuart Young, 2001. "Global energy prospects," Nature, Nature, vol. 414(6863), pages 487-488, November.
    2. Gu, Zhenhua & Li, Kongzhai & Wang, Hua & Qing, Shan & Zhu, Xing & Wei, Yonggang & Cheng, Xianming & Yu, He & Cao, Yan, 2016. "Bulk monolithic Ce–Zr–Fe–O/Al2O3 oxygen carriers for a fixed bed scheme of the chemical looping combustion: Reactivity of oxygen carrier," Applied Energy, Elsevier, vol. 163(C), pages 19-31.
    3. Charvin, Patrice & Abanades, Stéphane & Flamant, Gilles & Lemort, Florent, 2007. "Two-step water splitting thermochemical cycle based on iron oxide redox pair for solar hydrogen production," Energy, Elsevier, vol. 32(7), pages 1124-1133.
    4. Xiao, Lan & Wu, Shuang-Ying & Li, You-Rong, 2012. "Advances in solar hydrogen production via two-step water-splitting thermochemical cycles based on metal redox reactions," Renewable Energy, Elsevier, vol. 41(C), pages 1-12.
    5. Chen, Shiyi & Lior, Noam & Xiang, Wenguo, 2015. "Coal gasification integration with solid oxide fuel cell and chemical looping combustion for high-efficiency power generation with inherent CO2 capture," Applied Energy, Elsevier, vol. 146(C), pages 298-312.
    6. Ma, Jinchen & Zhao, Haibo & Tian, Xin & Wei, Yijie & Rajendran, Sharmen & Zhang, Yongliang & Bhattacharya, Sankar & Zheng, Chuguang, 2015. "Chemical looping combustion of coal in a 5kWth interconnected fluidized bed reactor using hematite as oxygen carrier," Applied Energy, Elsevier, vol. 157(C), pages 304-313.
    7. Penthor, Stefan & Zerobin, Florian & Mayer, Karl & Pröll, Tobias & Hofbauer, Hermann, 2015. "Investigation of the performance of a copper based oxygen carrier for chemical looping combustion in a 120kW pilot plant for gaseous fuels," Applied Energy, Elsevier, vol. 145(C), pages 52-59.
    8. Voitic, Gernot & Nestl, Stephan & Lammer, Michael & Wagner, Julian & Hacker, Viktor, 2015. "Pressurized hydrogen production by fixed-bed chemical looping," Applied Energy, Elsevier, vol. 157(C), pages 399-407.
    9. Lyngfelt, Anders, 2014. "Chemical-looping combustion of solid fuels – Status of development," Applied Energy, Elsevier, vol. 113(C), pages 1869-1873.
    10. Kathe, Mandar V. & Empfield, Abbey & Na, Jing & Blair, Elena & Fan, Liang-Shih, 2016. "Hydrogen production from natural gas using an iron-based chemical looping technology: Thermodynamic simulations and process system analysis," Applied Energy, Elsevier, vol. 165(C), pages 183-201.
    11. Bao, Jinhua & Li, Zhenshan & Cai, Ningsheng, 2014. "Interaction between iron-based oxygen carrier and four coal ashes during chemical looping combustion," Applied Energy, Elsevier, vol. 115(C), pages 549-558.
    12. Khan, Mohammed N. & Shamim, Tariq, 2016. "Investigation of hydrogen generation in a three reactor chemical looping reforming process," Applied Energy, Elsevier, vol. 162(C), pages 1186-1194.
    13. Cho, Won Chul & Lee, Do Yeon & Seo, Myung Won & Kim, Sang Done & Kang, KyoungSoo & Bae, Ki Kwang & Kim, Change Hee & Jeong, SeongUk & Park, Chu Sik, 2014. "Continuous operation characteristics of chemical looping hydrogen production system," Applied Energy, Elsevier, vol. 113(C), pages 1667-1674.
    Full references (including those not matched with items on IDEAS)

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    2. Zhu, Min & Chen, Shiyi & Soomro, Ahsanullah & Hu, Jun & Sun, Zhao & Ma, Shiwei & Xiang, Wenguo, 2018. "Effects of supports on reduction activity and carbon deposition of iron oxide for methane chemical looping hydrogen generation," Applied Energy, Elsevier, vol. 225(C), pages 912-921.
    3. Gao, Zixiang & Wu, Di & Yin, Fan & Sun, Liyan & Zeng, Dewang & Xiao, Rui, 2024. "Thermodynamic and kinetic analysis on the biomass syngas fueled chemical looping hydrogen generation process in fixed bed reactor," Energy, Elsevier, vol. 298(C).
    4. Turap, Yusan & Wang, Zhentong & Wang, Yidi & Zhang, Zhe & Chen, Siyuan & Wang, Wei, 2023. "High purity hydrogen production via coupling CO2 reforming of biomass-derived gas and chemical looping water splitting," Applied Energy, Elsevier, vol. 331(C).
    5. Zeng, Jimin & Xiao, Rui & Zhang, Shuai & Zhang, Huiyan & Zeng, Dewang & Qiu, Yu & Ma, Zhong, 2018. "Identifying iron-based oxygen carrier reduction during biomass chemical looping gasification on a thermogravimetric fixed-bed reactor," Applied Energy, Elsevier, vol. 229(C), pages 404-412.
    6. Cho, Won Chul & Lee, Doyeon & Kim, Chang Hee & Cho, Hyun Suk & Kim, Sang Done, 2018. "Feasibility study of the use of by-product iron oxide and industrial off-gas for application to chemical looping hydrogen production," Applied Energy, Elsevier, vol. 216(C), pages 466-481.
    7. Zeng, Jimin & Xiao, Rui & Yuan, Jun, 2021. "High-quality syngas production from biomass driven by chemical looping on a PY-GA coupled reactor," Energy, Elsevier, vol. 214(C).

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