Measurement of laminar burning velocity of high performance alternative aviation fuels

•Two high-density, moderate viscosity aviation fuels, HPF-1 and 2, were created.•Laminar burning velocities of the new fuels were measured using a Bunsen burner at an elevated temperature of 550 K.•Laminar burning velocities of the new fuels were found to be slightly higher than those of conventiona...

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Bibliographic Details
Published in:Fuel (Guildford) 2020-02, Vol.261, p.116466, Article 116466
Main Authors: Hwang, Byeong Jo, Kang, Saetbyeol, Lee, Hyung Ju, Min, Seongki
Format: Article
Language:English
Subjects:
Atmospheric models
Aviation fuel
Bunsen burner
Burning
Combustion
Engine design
Equivalence ratio
Flame surface area
Fuels
Heating
High energy density
High temperature
Hydrocarbon fuels
Jet engine fuels
Laminar flame speed
Liquid hydrocarbon
Velocity
Viscosity
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Summary:•Two high-density, moderate viscosity aviation fuels, HPF-1 and 2, were created.•Laminar burning velocities of the new fuels were measured using a Bunsen burner at an elevated temperature of 550 K.•Laminar burning velocities of the new fuels were found to be slightly higher than those of conventional aviation fuels.•Maximum laminar burning velocities were reached at equivalence ratios (Φmax) of 1.12–1.14.•The data can be used to develop and validate combustion models for the newly developed fuels. An experimental study was conducted on the measurement of the laminar burning velocity of alternative aviation fuels, in order to assess the feasibility of using the newly developed fuels in aviation applications. Two kinds of high performance hydrocarbon fuels (HPF-1 and 2), having higher density but moderate viscosity as compared with existing conventional aviation fuels, were created, and a Bunsen burner was manufactured to measure their laminar burning velocities at an elevated temperature of 550 K and atmospheric pressure. The measured laminar burning velocity of HPF-1 and 2 at the preheating temperature shows that the peak burning velocity of HPF-1 is approximately 125 cm/s, which is very close to that of the reference fuel (RF) and higher than Jet A-1, while the maximum laminar burning velocity of HPF-2 is shown to be approximately 130 cm/s, which is slightly higher (5–6 cm/s) than those of HPF-1 and RF. Compared with RF and Jet A-1, furthermore, the laminar burning velocity curves of HPFs shift to the fuel-rich side, with a corresponding decrease in the burning velocity on the lean side and an increase on the rich side. Therefore, the equivalence ratio where the laminar burning velocity reaches maximum (Φmax) increases slightly for the HPFs; Φmax for Jet A-1 and RF are around 1.07 and 1.08, respectively, while those for HPF-1 and 2 are 1.12 and 1.14, respectively. These fundamental data can be used to develop and validate combustion models to enable quantitative performance predictions in engine design for the newly developed fuels.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2019.116466