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Eco-efficiency analysis and intensification of the biodiesel production process through vapor recompression strategy

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  • Guedes do Nascimento, Leomário
  • Costa Monteiro, Luciane Pimentel
  • de Cássia Colman Simões, Rita
  • Prata, Diego Martinez

Abstract

Biodiesel production has increased worldwide with the potential for developing renewable and sustainable energy technologies and its intensification using a vapor recompression strategy is studied in this paper. The conventional process design and the proposed intensification were designed by computer simulation in UniSim Software. A utility plant with cooling water and steam generation sections was also considered for more accurate results regarding water consumption, CO2 emissions, and utility costs. Finally, in order to establish an overall means for performance analysis, such indicators were grouped in a joint evaluation approach using the Comparative Eco-Efficiency Index. The vapor recompression technology applied to biodiesel production from waste cooking oil proved to be a convenient strategy since it significantly improved the original process performance, with reductions of 65.9% in water consumption, 68.4% in CO2 emissions, 56.6% in utility costs, and consequently increased the process' eco-efficiency by 86.9%. This is in accordance with the United Nations' sustainable development goals as well as improves the competitiveness of biodiesel on the market.

Suggested Citation

  • Guedes do Nascimento, Leomário & Costa Monteiro, Luciane Pimentel & de Cássia Colman Simões, Rita & Prata, Diego Martinez, 2023. "Eco-efficiency analysis and intensification of the biodiesel production process through vapor recompression strategy," Energy, Elsevier, vol. 275(C).
    • Handle: RePEc:eee:energy:v:275:y:2023:i:c:s0360544223008733
    DOI: 10.1016/j.energy.2023.127479
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