4.7 Article

Diesel blends produced via emulsification of hydrothermal liquefaction biocrude from food waste

Journal

FUEL
Volume 324, Issue -, Pages -

Publisher

ELSEVIER SCI LTD
DOI: 10.1016/j.fuel.2022.124817

Keywords

Food waste; Hydrothermal liquefaction; Biocrude oil; Emulsification; Biofuel upgrading; Diesel blend

Funding

  1. U.S. Army Engineer Research and Development Center [FAIN: W9132T2020005]
  2. College of Agricultural, Consumer and Environmental Sciences, University of Illinois at Urbana-Champaign Jonathan Baldwin Turner Graduate Fellowship
  3. James Scholar Program for undergraduates

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This study investigated the production and fuel quality of diesel blends through emulsification of HTL biocrude using centrifugation and ultrasonification. The emulsion treatment improved the HHV, viscosity, and TAN of the fuel blends compared to the HTL biocrude oil, achieving high solubility levels with surfactant addition and increased retention time. The emulsions had maximum biocrude solubilities of 65.43 wt% for centrifugation and 75.67 wt% for ultrasonification, and the highest HHV was 45.39 MJ/kg for centrifuge emulsion and 45.73 MJ/kg for ultrasonic emulsion. Emulsification led to lower viscosities (5.91 and 6.06 mm2/s) and TAN values (14.18-41.31 for centrifugation, 16.22-50.31 for ultrasonification) compared to the biocrude. The study demonstrates that emulsification of HTL biocrude is an efficient and economical pathway for producing renewable diesel blends.
Hydrothermal liquefaction (HTL) is a promising method for producing biocrude oil from wet biowaste. However, the complex composition of the HTL biocrude has several undesirable qualities, including high viscosity, total acid number (TAN), oxygen and nitrogen heteroatom content, and lesser higher heating value (HHV) in comparison to petroleum fuels. This study investigated the production of diesel blends and their fuel quality by emulsification of HTL biocrude with the aid of a block copolymer surfactant through centrifugation and ultrasonification. Four emulsion treatment variables were considered: biocrude fraction, surfactant fraction, retention time, and RPM (rotations per minute) for centrifuge or temperature for ultrasonic. Emulsification produced fuel blends with better HHV, viscosity, and TAN in comparison to HTL biocrude oil, and high solubility levels were achieved with surfactant addition and increased retention time. Maximum biocrude solubilities of 65.43 and 75.67 wt% were obtained for centrifugation and ultrasonification, respectively. Meanwhile, the highest HHV of centrifuge and ultrasonic emulsions was 45.39 and 45.73 MJ/kg, respectively. Emulsification led to viscosities as low as 5.91 and 6.06 mm2/s for centrifuge and ultrasonic samples, respectively. The TAN of emulsions were much lower than the biocrude: 14.18-41.31 and 16.22-50.31 mg KOH/g for centrifugation and ultrasonification, respectively. Thermogravimetric analysis, elemental analysis, combustion characteristics, and thermal properties gave further insight into the fuel quality of the emulsions and any deviations from the predicted HHV, viscosity, and TAN fuel properties, as well as comparison to ASTM specifications for biodiesel blends. The results show that emulsification of HTL biocrude could be an efficient and economical pathway for producing renewable diesel blends.

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