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Clathrate hydrate formation of CO2/CH4 mixture at room temperature: Application to direct transport of CO2-containing natural gas

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  • Zheng, Junjie
  • Loganathan, Niranjan Kumar
  • Zhao, Jianzhong
  • Linga, Praveen

Abstract

CO2 is one of the major contaminants in natural gas produced from the reservoir. Many gas fields are not monetized due to the presence of high levels of CO2 in the natural gas reservoir (in some locations, as high as 80%). SNG (solidified natural gas) technology provides a potential method to directly transport CO2-containing natural gas in the form of gas hydrates. We examined the performance of hydrate formation for 24% CO2/76% CH4 mixture in the presence of stoichiometric tetrahydrofuran (THF, 5.56 mol%) in an unstirred tank reactor (UTR). The presence of 24% CO2 exhibited two contrasting kinetic behaviors for CO2/CH4/THF hydrate formation. Considering only the high-kinetics cases, the hydrate formation kinetics was significantly enhanced by increasing the experimental pressure from 3.0 MPa to 7.0 MPa at 283.2 K. The increase of experimental temperature from 283.2 K to 293.2 K at 7.0 MPa reduced the gas uptake by around 40%. We observed different morphology patterns during hydrate formation under different temperatures. By the addition of a kinetic promoter, 100 ppm sodium dodecyl sulfate (SDS), and applying a hybrid formation method involving a very short period of stirring at the beginning and unstirred operation during the hydrate growth stage, we achieved rapid hydrate formation of 75.40 ± 2.62 mmol/mol within 2 h with extremely short induction time (11.3 ± 4.79 min) at room temperature (298.2 K) and 9.1 MPa. The simplicity of this process and the enhanced kinetic performance at room temperature could result in an overall cost reduction making it feasible to develop an economical transport method for CO2-containing natural gas.

Suggested Citation

  • Zheng, Junjie & Loganathan, Niranjan Kumar & Zhao, Jianzhong & Linga, Praveen, 2019. "Clathrate hydrate formation of CO2/CH4 mixture at room temperature: Application to direct transport of CO2-containing natural gas," Applied Energy, Elsevier, vol. 249(C), pages 190-203.
    • Handle: RePEc:eee:appene:v:249:y:2019:i:c:p:190-203
    DOI: 10.1016/j.apenergy.2019.04.118
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    Cited by:

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    2. Zhang, Qiang & Zheng, Junjie & Zhang, Baoyong & Linga, Praveen, 2021. "Coal mine gas separation of methane via clathrate hydrate process aided by tetrahydrofuran and amino acids," Applied Energy, Elsevier, vol. 287(C).
    3. Liu, Fa-Ping & Li, Ai-Rong & Wang, Cheng & Ma, Yu-Ling, 2023. "Controlling and tuning CO2 hydrate nucleation and growth by metal-based ionic liquids," Energy, Elsevier, vol. 269(C).
    4. Yiwei Wang & Lin Wang & Zhen Hu & Youli Li & Qiang Sun & Aixian Liu & Lanying Yang & Jing Gong & Xuqiang Guo, 2021. "The Thermodynamic and Kinetic Effects of Sodium Lignin Sulfonate on Ethylene Hydrate Formation," Energies, MDPI, vol. 14(11), pages 1-19, June.
    5. Zhang, Qiang & Zheng, Junjie & Zhang, Baoyong & Linga, Praveen, 2023. "Kinetic evaluation of hydrate-based coalbed methane recovery process promoted by structure II thermodynamic promoters and amino acids," Energy, Elsevier, vol. 274(C).
    6. Zheng Li & Christine C. Holzammer & Andreas S. Braeuer, 2020. "Analysis of the Dissolution of CH 4 /CO 2 -Mixtures into Liquid Water and the Subsequent Hydrate Formation via In Situ Raman Spectroscopy," Energies, MDPI, vol. 13(4), pages 1-17, February.
    7. Sun, Jiyue & Jiang, Lei & Chou, I Ming & Nguyen, Ngoc N. & Nguyen, Anh V. & Chen, Ying & Lin, Juezhi & Wu, Chuanjun, 2023. "Thermodynamic and kinetic study of methane hydrate formation in surfactant solutions: From macroscale to microscale," Energy, Elsevier, vol. 282(C).
    8. Kawasaki, Toshiyuki & Obara, Shin'ya, 2020. "CO2 hydrate heat cycle using a carbon fiber supported catalyst for gas hydrate formation processes," Applied Energy, Elsevier, vol. 269(C).

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