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Integration of CO2 cryogenic removal with a natural gas pressurized liquefaction process using gas expansion refrigeration

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  • Xiong, Xiaojun
  • Lin, Wensheng
  • Gu, Anzhong

Abstract

Space limitation is a great challenge in offshore liquefied natural gas production. A novel natural gas liquefaction process aimed at footprint reduction is first proposed in this study. The novel process uses pressurized liquefaction technology to decrease the size of the heat exchanger, and it adopts CO2 cryogenic removal to eliminate the large CO2 pretreatment facility so as to achieve a small footprint. Since energy consumption is always a big concern for a natural gas liquefaction process, this study performs optimization for the proposed process. Taking the specific power consumption as the objective function, the proposed process is optimized by the sequential search method using HSYSY simulation. In this study, the proposed processes with and without precooling are both studied and the effect of precooling is discussed. Various refrigerants are employed in the proposed processes and their optimal performances are compared and analyzed. Furthermore, natural gas with different CO2 contents is used as feed gas to investigate the effect of CO2 content on energy consumption. In conclusion, the proposed novel process with a small footprint and low energy consumption provides a promising option for offshore liquefied natural gas production.

Suggested Citation

  • Xiong, Xiaojun & Lin, Wensheng & Gu, Anzhong, 2015. "Integration of CO2 cryogenic removal with a natural gas pressurized liquefaction process using gas expansion refrigeration," Energy, Elsevier, vol. 93(P1), pages 1-9.
  • Handle: RePEc:eee:energy:v:93:y:2015:i:p1:p:1-9
    DOI: 10.1016/j.energy.2015.09.022
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    References listed on IDEAS

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    Cited by:

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    3. Li, Yong & Xie, Gongnan & Sunden, Bengt & Lu, Yuanwei & Wu, Yuting & Qin, Jiang, 2018. "Performance study on a single-screw compressor for a portable natural gas liquefaction process," Energy, Elsevier, vol. 148(C), pages 1032-1045.
    4. Baccanelli, Margaret & Langé, Stefano & Rocco, Matteo V. & Pellegrini, Laura A. & Colombo, Emanuela, 2016. "Low temperature techniques for natural gas purification and LNG production: An energy and exergy analysis," Applied Energy, Elsevier, vol. 180(C), pages 546-559.
    5. Siahvashi, Arman & Al Ghafri, Saif Z.S. & Yang, Xiaoxian & Rowland, Darren & May, Eric F., 2021. "Avoiding costly LNG plant freeze-out-induced shutdowns: Measurement and modelling for neopentane solubility at LNG conditions," Energy, Elsevier, vol. 217(C).
    6. Lin, Wensheng & Xiong, Xiaojun & Gu, Anzhong, 2018. "Optimization and thermodynamic analysis of a cascade PLNG (pressurized liquefied natural gas) process with CO2 cryogenic removal," Energy, Elsevier, vol. 161(C), pages 870-877.
    7. Mofid, Hossein & Jazayeri-Rad, Hooshang & Shahbazian, Mehdi & Fetanat, Abdolvahhab, 2019. "Enhancing the performance of a parallel nitrogen expansion liquefaction process (NELP) using the multi-objective particle swarm optimization (MOPSO) algorithm," Energy, Elsevier, vol. 172(C), pages 286-303.
    8. Song, Rui & Cui, Mengmeng & Liu, Jianjun, 2017. "Single and multiple objective optimization of a natural gas liquefaction process," Energy, Elsevier, vol. 124(C), pages 19-28.
    9. Lei Gao & Jiaxin Wang & Maxime Binama & Qian Li & Weihua Cai, 2022. "The Design and Optimization of Natural Gas Liquefaction Processes: A Review," Energies, MDPI, vol. 15(21), pages 1-56, October.
    10. Kwak, Dong-Hun & Heo, Jeong-Ho & Park, Seung-Ha & Seo, Seok-Jang & Kim, Jin-Kuk, 2018. "Energy-efficient design and optimization of boil-off gas (BOG) re-liquefaction process for liquefied natural gas (LNG)-fuelled ship," Energy, Elsevier, vol. 148(C), pages 915-929.
    11. Li, Hongwei & Zhang, Rongjun & Wang, Tianye & Wu, Yu & Xu, Run & Wang, Qiang & Tang, Zhigang, 2022. "Performance evaluation and environment risk assessment of steel slag enhancement for seawater to capture CO2," Energy, Elsevier, vol. 238(PB).

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