4.6 Article

Autoignition characteristics of bio-based fuels, farnesane and TPGME, in comparison with fuels of similar cetane rating

Journal

PROCEEDINGS OF THE COMBUSTION INSTITUTE
Volume 38, Issue 4, Pages 5585-5595

Publisher

ELSEVIER SCIENCE INC
DOI: 10.1016/j.proci.2020.05.055

Keywords

Autoignition characteristics; bio-based alternative fuel; cetane number; CFR engine; CID instrument

Funding

  1. National Natural Science Foundation of China [51906043]
  2. Natural Science Foundation of Jiangsu Province [BK20190363]
  3. National Science Foundation for Distinguished Young Scientists of China [51525601]
  4. Department of Mechanical Engineering at the University of Michigan
  5. State Key Laboratory of Engines, Tianjin University

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Bio-based alternative fuels are gaining attention due to concerns about fossil reserves depletion and environmental deterioration. This study investigates the autoignition characteristics of two alternative fuels, farnesane and TPGME, and compares them with full-boiling range fuels with similar cetane number. The results show that farnesane has stronger ignition reactivity than HRJ8, while TPGME exhibits greater low-temperature oxidation reactivity compared to n-heptane.
Bio-based alternative fuels have received increasing attention with growing concerns about depletion of fossil reserves and environmental deterioration. The development of new combustion concepts in internal combustion engines requires a better understanding of autoignition characteristics of the bio-based alternative fuels. This study investigates two cases of alternative fuels, namely, a kerosene-type fuel farnesane and an oxygenated fuel, TPGME, and compares those fuels with full-boiling range of fuels with similar cetane number. The homogeneous autoignition and spray ignition characteristics of the selected fuels are studied using a modified CFR octane rating engine and a cetane rating instrument, respectively. When comparing farnesane with a full-boiling range counterpart (HRJ8), their similar cetane ratings result in comparable combustion heat release, but the overall ignition reactivity of farnesane is stronger than HRJ8 during the pre-ignition process. Results from a constant volume spray combustion chamber indicate that the spray process of farnesane and HRJ8 strongly influences the overall ignition delay of each fuel. Despite the similar cetane ratings of TPGME and n-heptane, TPGME shows greater apparent low-temperature oxidation reactivity at low compression ratios in the range from CR 4.0-5.5 than n-heptane. A simplified model focused on the key reaction pathways of low-temperature oxidation of TPGME has been applied to account for the stronger low-temperature reactivity of TPGME, supported by density functional theory (DFT) calculations. Regardless of the similar cetane ratings of the fuels, n-heptane and JP-8/SPK lead to similar total ignition delay times, while TPGME shows the shortest overall ignition delay times in the constant volume combustion chamber. (c) 2020 The Combustion Institute. Published by Elsevier Inc. All rights reserved.

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