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Analysis of high-pressure hydrogen, methane, and heptane laminar diffusion flames: Thermal diffusion factor modeling

Journal Article · · Combustion and Flame
;  [1]
  1. Department of Mechanical Engineering, Clemson University, Clemson, SC 29634-0921 (United States)
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Direct numerical simulations are conducted for one-dimensional laminar diffusion flames over a large range of pressures (1{<=}P{sub 0}{<=}200atm) employing a detailed multicomponent transport model applicable to dense fluids. Reaction kinetics mechanisms including pressure dependencies and prior validations at both low and high pressures were selected and include a detailed 24-step, 12-species hydrogen mechanism (H{sub 2}/O{sub 2} and H{sub 2}/air), and reduced mechanisms for methane (CH{sub 4}/air: 11 steps, 15 species) and heptane (C{sub 7}H{sub 16}/air: 13 steps, 17 species), all including thermal NO{sub x} chemistry. The governing equations are the fully compressible Navier-Stokes equations, coupled with the Peng-Robinson real fluid equation of state. A generalized multicomponent diffusion model derived from nonequilibrium thermodynamics and fluctuation theory is employed and includes both heat and mass transport in the presence of concentration, temperature, and pressure gradients (i.e., Dufour and Soret diffusion). Previously tested high-pressure mixture property models are employed for the viscosity, heat capacity, thermal conductivity, and mass diffusivities. Five models for high-pressure thermal diffusion coefficients related to Soret and Dufour cross-diffusion are first compared with experimental data over a wide range of pressures. Laminar flame simulations are then conducted for each of the four flames over a large range of pressures for all thermal diffusion coefficient models and results are compared with purely Fickian and Fourier diffusion simulations. The results reveal a considerable range in the influence of cross-diffusion predicted by the various models; however, the most plausible models show significant cross-diffusion effects, including reductions in the peak flame temperatures and minor species concentrations for all flames. These effects increase with pressure for both H{sub 2} flames and for the C{sub 7}H{sub 16} flames indicating the elevated importance of proper cross-diffusion modeling at large pressures. Cross-diffusion effects, while not negligible, were observed to be less significant in the CH{sub 4} flames and to decrease with pressure. Deficiencies in the existing thermal diffusion coefficient models are discussed and future research directions suggested. (author)
OSTI ID:
20975386
Journal Information:
Combustion and Flame, Journal Name: Combustion and Flame Journal Issue: 4 Vol. 151; ISSN CBFMAO; ISSN 0010-2180
Country of Publication:
United States
Language:
English

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Related Subjects

37 INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
AIR
CHEMICAL REACTION KINETICS
COMBUSTION PROPERTIES
FLUCTUATIONS
HEAT TRANSFER
HEPTANE
HYDROGEN
LAMINAR FLAMES
MASS TRANSFER
METHANE
NAVIER-STOKES EQUATIONS
NITROGEN OXIDES
ONE-DIMENSIONAL CALCULATIONS
PRESSURE GRADIENTS
PRESSURE RANGE KILO PA
PRESSURE RANGE MEGA PA 01-10
PRESSURE RANGE MEGA PA 10-100
SIMULATION
SPECIFIC HEAT
TEMPERATURE GRADIENTS
THERMAL CONDUCTIVITY
THERMAL DIFFUSION
VISCOSITY