posted on 2022-01-20, 18:09authored byFlorence
H. Vermeire, Syam Ukkandath Aravindakshan, Agnes Jocher, Mengjie Liu, Te-Chun Chu, Ryan E. Hawtof, Ruben Van de Vijver, Matthew B. Prendergast, Kevin M. Van Geem, William H. Green
Fuel microchannels for regenerative
cooling are receiving increasing
attention in advanced aviation technologies. Those microchannels allow
heat integration between the endothermic cracking of the jet fuels
and their subsequent combustion. In this work, a detailed elementary-step
kinetic model is developed to gain insights into the cracking chemistry
of a Jet A surrogate (n-dodecane, isooctane, n-propyl benzene, and 1,3,5-trimethylbenzene), which allows
for further optimization of those aviation technologies. A dedicated
procedure is described for the automated generation of kinetic models
for multi-component mixtures with the open-source Reaction Mechanism
Generator (RMG) software. The full kinetic model is validated against
experimental measurements in multiple reactor geometries, under various
experimental conditions, including both a surrogate mixture and a
commercial Jet A. The experimental data include new experimental measurements
for the pyrolysis of a Jet A surrogate in a tubular reactor with a
detailed product analysis using comprehensive 2D GC. The good performance
of the kinetic model for data from a broad range of experimental conditions
demonstrates the advantage of a kinetic model with detailed chemistry
against empirical kinetic models that are limited in their applicability
range. Further analysis of the important chemistry in the kinetic
model shows that it is essential to account for cross-reactions between
the different surrogate components.