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Catalytic conversion of triglycerides by metal-based catalysts and subsequent modification of molecular structure by ZSM-5 and Raney Ni for the production of high-value biofuel

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  • Long, Feng
  • Zhai, Qiaolong
  • Liu, Peng
  • Cao, Xincheng
  • Jiang, Xia
  • Wang, Fei
  • Wei, Linshan
  • Liu, Chao
  • Jiang, Jianchun
  • Xu, Junming

Abstract

We report herein a catalytic deoxygenation strategy that allows the direct removal of oxygen atoms from triglycerides by lowering the activation energy through the use of metal-based catalysts. Activation energies were investigated by TG analysis, employing fatty acid salts as model compounds. Introducing different metal atoms into carboxyl groups has a substantial effect on the dynamic pyrolytic behavior, and decomposition activation energies varied in the range 80–260 kJ/mol. The catalytic cracking of soybean oil using SnO as a representative catalyst has been investigated in a 5 L reactor, whereby the catalyst lowered the decomposition temperature by approximately 40 °C and gave a conversion rate of approximately 66 wt%. A catalytic conversion mechanism has been proposed based on the results of TG-FTIR, GC, and GC-MS analyses. The pyrolysis products from the deoxygenation process had a high alkene content, endowing them with great potential for conversion into cyclic hydrocarbons used in real aviation fuels. Such conversion through aromatization and hydrogenation over ZSM-5 and Raney Ni catalyst has been investigated. Overall, a new refining process, including conversion of triglycerides to alkanes and terminal alkenes catalyzed by metal compounds, furnishing viable aviation and diesel fuels, is reported.

Suggested Citation

  • Long, Feng & Zhai, Qiaolong & Liu, Peng & Cao, Xincheng & Jiang, Xia & Wang, Fei & Wei, Linshan & Liu, Chao & Jiang, Jianchun & Xu, Junming, 2020. "Catalytic conversion of triglycerides by metal-based catalysts and subsequent modification of molecular structure by ZSM-5 and Raney Ni for the production of high-value biofuel," Renewable Energy, Elsevier, vol. 157(C), pages 1072-1080.
    • Handle: RePEc:eee:renene:v:157:y:2020:i:c:p:1072-1080
    DOI: 10.1016/j.renene.2020.05.117
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    References listed on IDEAS

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    1. Tan, Qihang & Cao, Yang & Li, Jin, 2020. "Prepared multifunctional catalyst Ni2P/Zr-SBA-15 and catalyzed Jatropha Oil to produce bio-aviation fuel," Renewable Energy, Elsevier, vol. 150(C), pages 370-381.
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    6. Ramesh, Arumugam & Tamizhdurai, Perumal & Shanthi, Kannan, 2019. "Catalytic hydrodeoxygenation of jojoba oil to the green-fuel application on Ni-MoS/Mesoporous zirconia-silica catalysts," Renewable Energy, Elsevier, vol. 138(C), pages 161-173.
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    2. Wang, Xin & Jin, Xiaodong & Wang, Hui & Wang, Yi & Zuo, Lu & Shen, Boxiong & Yang, Jiancheng, 2023. "Catalytic pyrolysis of microalgal lipids to liquid biofuels: Metal oxide doped catalysts with hierarchically porous structure and their performance," Renewable Energy, Elsevier, vol. 212(C), pages 887-896.
    3. Verma, Vikas & Mishra, Ankit & Anand, Mohit & Farooqui, Saleem Akhtar & Sinha, Anil Kumar, 2022. "Catalytic hydrocracking of inedible palm stearin for the production of drop-in aviation fuel and comparison with other inedible oils," Renewable Energy, Elsevier, vol. 199(C), pages 1440-1450.
    4. Singh, Omvir & Agrawal, Ankit & Dhiman, Neha & Vempatapu, Bhanu Prasad & Chiang, Ken & Tripathi, Shailendra & Sarkar, Bipul, 2021. "Production of renewable aromatics from jatropha oil over multifunctional ZnCo/ZSM-5 catalysts," Renewable Energy, Elsevier, vol. 179(C), pages 2124-2135.

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