1. Development of a laminar burning velocity empirical correlation forcombustion of iso-octane/ethanol blends in air
- Author
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Varun Shankar, Nikola Sekularac, Felix Leach, Xiaohang Fang, S.J. Baker, and Martin H. Davy
- Subjects
Ethanol ,Materials science ,General Chemical Engineering ,Organic Chemistry ,Mixing (process engineering) ,Energy Engineering and Power Technology ,Thermodynamics ,Laminar flow ,Combustion ,Chemical kinetics ,chemistry.chemical_compound ,Fuel Technology ,Temperature and pressure ,chemistry ,Octane ,Bar (unit) - Abstract
This study presents the first demonstration of Marshall and Hinton’s empirical correlation for laminar burning velocity (LBV) applied to iso-octane/ethanol blends. The “Oxford” correlation is first validated for neat iso-octane and ethanol combustion against the outputs of three different chemical kinetics mechanisms and experimental data from the literature. The effects of three different mixing rules, simple energy fraction, modified Le Châtelier, and modified version of the more complex mixing law of Hirasawa, on the predicted LBVs of iso-octane/ethanol blends are evaluated. The modified Le Châtelier mixing law is used with the Oxford correlation to predict blend LBVs at various temperature and pressure conditions. The results are validated against previously unpublished data for iso-octane/ethanol binary fuels at elevated temperature and pressure (up to 10 bar) both from this group, and from the earlier experimental studies of Varea et al. (CORIA) and Broustail et al. (PRISME). The Oxford correlation is shown to perform well across a wide range of temperature and pressure conditions (respectively 298–640 K and 1–10 bar) for the single component fuels. Used in conjunction with a modified Le Châtelier mixing law, the LBVs predicted by the correlation provide an excellent match to the available experimental data across the full range of ethanol concentrations examined (25, 50, and 75% v/v).
- Published
- 2021
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