Influence of Strouhal number on pulsating methane–air coflow jet diffusion flames
DOI10.1080/13647830.2010.490048zbMath1197.80054OpenAlexW2061815173MaRDI QIDQ4931827
Mitchell D. Smooke, Beth Anne Bennett, Amable Liñán, Mario Sánchez-Sanz
Publication date: 1 October 2010
Published in: Combustion Theory and Modelling (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1080/13647830.2010.490048
Navier-Stokes equations for incompressible viscous fluids (76D05) Finite difference methods applied to problems in fluid mechanics (76M20) Combustion (80A25) Chemically reacting flows (80A32) Finite difference methods applied to problems in thermodynamics and heat transfer (80M20)
Related Items (4)
Cites Work
- Error estimate for the modified Newton method with applications to the solution of nonlinear, two-point boundary-value problems
- Vorticity-velocity formulation for three-dimensional steady compressible flows
- A modified Newton method for the solution of ill-conditioned systems of nonlinear equations with application to multiple shooting
- A mass-conserving vorticity-velocity formulation with application to nonreacting and reacting flows
- Computational and experimental study of oxygen-enhanced axisymmetric laminar methane flames
- A planar pulsating jet
- Bi-CGSTAB: A Fast and Smoothly Converging Variant of Bi-CG for the Solution of Nonsymmetric Linear Systems
- Local rectangular refinement with application to axisymmetric laminar flames
- Towards Polyalgorithmic Linear System Solvers for Nonlinear Elliptic Problems
- Numerical simulation of laminar reacting flows with complex chemistry
- Direct simulation of non-premixed flame extinction in a methane–air jet with reduced chemistry
- Distributed-memory parallel computation of a forced, time-dependent, sooting, ethylene/air coflow diffusion flame
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