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Analyzing flue gas properties emitted from power and industrial sectors toward heat-integrated carbon capture

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  • Yagihara, Koki
  • Ohno, Hajime
  • Guzman-Urbina, Alexander
  • Ni, Jialing
  • Fukushima, Yasuhiro

Abstract

Carbon capture, utilization, and storage (CCUS) is expected to mitigate CO2 emissions significantly since CO2 is captured from the flue gas emitted by power and industrial processes and then either used in manufacturing processes or sequestrated into geographical formations. CO2 capture is an energy-intensive process, and its energy consumption is affected by flue gas properties such as composition and flue gas temperature. In this study, we explore the availability of the unutilized heat carried by the flue gas for CO2 capturing emitted from power and industrial sectors based on the fundamentals of fuel combustion and types of combustion processes. This study reveals that the input of fuel and material and the thermal properties of energy equipment determine the flue gas properties. By quantifying the maximum heat recovered from the flue gas, natural gas-fired furnaces can fully supply heat duty for capturing CO2 when 2.75 MJ per CO2 is captured with the minimum temperature difference greater than ∼48 °C. This study provides general insight into the heat-integrated CO2 capture using flue gases.

Suggested Citation

  • Yagihara, Koki & Ohno, Hajime & Guzman-Urbina, Alexander & Ni, Jialing & Fukushima, Yasuhiro, 2022. "Analyzing flue gas properties emitted from power and industrial sectors toward heat-integrated carbon capture," Energy, Elsevier, vol. 250(C).
    • Handle: RePEc:eee:energy:v:250:y:2022:i:c:s0360544222006788
    DOI: 10.1016/j.energy.2022.123775
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    References listed on IDEAS

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    1. Psarras, Peter C. & Comello, Stephen & Bains, Praveen & Charoensawadpong, Panunya & Reichelstein, Stefan J. & Wilcox, Jennifer, 2017. "Carbon Capture and Utilization in the Industrial Sector," Research Papers repec:ecl:stabus:3493, Stanford University, Graduate School of Business.
    2. Yoro, Kelvin O. & Daramola, Michael O. & Sekoai, Patrick T. & Armah, Edward K. & Wilson, Uwemedimo N., 2021. "Advances and emerging techniques for energy recovery during absorptive CO2 capture: A review of process and non-process integration-based strategies," Renewable and Sustainable Energy Reviews, Elsevier, vol. 147(C).
    3. Oh, Se-Young & Binns, Michael & Cho, Habin & Kim, Jin-Kuk, 2016. "Energy minimization of MEA-based CO2 capture process," Applied Energy, Elsevier, vol. 169(C), pages 353-362.
    4. Wang, Yufei & Chang, Chenglin & Feng, Xiao, 2015. "A systematic framework for multi-plants Heat Integration combining Direct and Indirect Heat Integration methods," Energy, Elsevier, vol. 90(P1), pages 56-67.
    5. Guo, Liheng & Ding, Yudong & Liao, Qiang & Zhu, Xun & Wang, Hong, 2022. "A new heat supply strategy for CO2 capture process based on the heat recovery from turbine exhaust steam in a coal-fired power plant," Energy, Elsevier, vol. 239(PA).
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    1. Ilea, Flavia-Maria & Cormos, Ana-Maria & Cristea, Vasile-Mircea & Cormos, Calin-Cristian, 2023. "Enhancing the post-combustion carbon dioxide carbon capture plant performance by setpoints optimization of the decentralized multi-loop and cascade control system," Energy, Elsevier, vol. 275(C).
    2. Zemin Ji & Qun Zhang & Yang Gao & Jing Wang & Chang He & Lu Han & Wenjing Zhao, 2022. "Experimental Study on Conformance Control Using Acidic Nanoparticles in a Heterogeneous Reservoir by Flue Gas Flooding," Energies, MDPI, vol. 16(1), pages 1-12, December.
    3. Fu, Yue & Wang, Liyuan & Liu, Ming & Wang, Jinshi & Yan, Junjie, 2023. "Performance analysis of coal-fired power plants integrated with carbon capture system under load-cycling operation conditions," Energy, Elsevier, vol. 276(C).

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