4.7 Article

Numerical investigation of multi-component droplet evaporation and autoignition for aero-engine applications

Journal

COMBUSTION AND FLAME
Volume 241, Issue -, Pages -

Publisher

ELSEVIER SCIENCE INC
DOI: 10.1016/j.combustflame.2022.112023

Keywords

Preferential evaporation; Multi-component kerosene surrogate; Spray combustion; Aero -engine combustor; Aviation fuel; MILD combustion

Funding

  1. Clean Sky 2 Joint Undertaking (JU) [831804]
  2. European Union's Horizon 2020 research and innovation programme

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This study numerically investigates the evaporation and autoignition behavior of a three-component kerosene surrogate under various operating conditions. The results show that gas temperature affects preferential evaporation and droplet composition, while pressure and dilution level have a significant impact on autoignition. Droplet preheating can be used as a design parameter to control autoignition delay time.
The droplet evaporation and autoignition behaviour of a three-component kerosene surrogate is numerically investigated for a wide range of ambient pressures and temperatures representing realistic aeroengine conditions. Vitiated air with different levels of dilution is considered to represent mixing of air with combustion products. Particular attention is given to the analysis of multi-component fuel effects at the various operating conditions. The investigation also considers the impact of fuel preheating and multiple initial droplet diameters, and extends to the quantification of NO x emissions at the droplet scale level. Considering pure evaporation, results show that preferential evaporation and variation of the droplet composition are mainly affected by the gas temperature. An increase of the pressure generally increases the duration of the droplet heat-up period and reduces the effects of preferential evaporation, especially when high temperatures are considered. Autoignition in vitiated air is strongly influenced by both the level of dilution and ambient pressure, with the latter playing an important role in determining the value of the initial droplet diameter below which no autoignition occurs. Lower pressures generally make the kerosene droplet more resistant to autoignition for the same level of dilution or gas temperature. Droplet preheating mainly affects the heat-up period and can be used as a design parameter to control the autoignition delay time. NO x levels are substantially related to the gas-phase temperature and the existence of a flame at the droplet scale. Potential implications for the design of future low-emission combustor technologies are discussed with an emphasis on the fuel preparation. (c) 2022 The Combustion Institute. Published by Elsevier Inc. All rights reserved.

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