Flamelet modeling for combustion processes and NOx formation in the turbulent nonpremixed CO/H2/N2 jet flames

Combustion Science and Technology

Volumn 168, Issue 1, 2001, Pages 47-83

  Kim, Seong Ku ^a   Kang, Sung Mo ^a   Kim, Yong Mo ^a  

^a Hanyang University   (South Korea)

Author keywords

[No Author keywords available]

Indexed keywords

DIFFUSION IN GASES; FINITE VOLUME METHOD; FLAME RESEARCH; NITROGEN OXIDES; NOZZLES; REYNOLDS NUMBER; TEMPERATURE; TURBULENCE;

DIAMETER; JET FLAMES; STEADY FLAMELET; UNSTEADY FLAMELET;

COMBUSTION;

EID: 0038395684     PISSN: 00102202     EISSN: None     Source Type: Journal    
DOI: 10.1080/00102200108907831     Document Type: Article

References (32)

1. 2 jet flames. Combustion and Flame 120:549.
2. 2 flame data-Release 1.0, available on the web at www.ca.sandia.gov/tdf/Workshop html.
3. Barlow, R. S., N. S. A. Smith, J. Y. Chen, and R. W. Bilger. 1999. Nitric oxide formation in dilute hydrogen jet flames: Isolation of the effects of radiation and turbulence-chemistry submodels. Combustion and Flame 117:4.
4. Barths, H., N. Peters, N. Brehm, A. Mack, M. Pfitzner, and V. Smiljanovski. 1998. Simulation of pollutant formation in a gas-turbine combustor using unsteady flamelets, Proc. 27th Symp. (Int.) Comb., Pittsburgh, PA: Combustion Institute, 1841.
5. Bilger, R. W. 1988. The structure of turbulent nonpremixed flames, Proc. 22nd Symp. (Int.) Comb., Pittsburgh, PA: Combustion Institute, 475.
6. Chen, M., M. Herrmann, and N. Peters. 2000. Flamelet modeling of lifted turbulent methane/air and propane/air jet diffusion flames, Proc. 28th Symp. (Int.) Comb., Pittsburgh, Combustion Institute, PA: 167.
7. Ferreira, J. C. 1996. Flamelet Modelling of Stabilization in Turbulent Non-premixed Combustion, PhD Thesis, ETHZ-Zurich, Switzerland.
8. Frank, J. H., R. S. Barlow, and C. Lundquist. 2000. Radiation and nitric oxide formation in turbulent nonpremixed jet flames, Proc. 28th Symp. (Int.) Comb., Pittsburgh, PA: Combustion Institute, 447.
9. Grcar, J. F. 1992. The Twopnt Program for Boundary Value Problems, Sandia Report, SAND91-8320, Livermore.
10. Hewson, J. C. 1997. Pollutant Emissions from Nonpremixed Hydrocarbon Flames, PhD Thesis, University of California, San Diego.
11. Kim, S. H., K. Y. Huh, and L. Tao. 2000. Application of the elliptic conditional moment closure model to a two-dimensional nonpremixed methanol bluff-body flame. Combustion and Flame 120:75.
12. Kim, Y. M. 1999. Unstructured-grid finite-volume method for analyzing incompressible flows, Proceedings of Spring Fluid Engineering Workshop, KSME, p. 128.
13. Klimenko, A. Y., and R. W. Bilger. 1999. Conditional moment closure for turbulent combustion. Prog. Energy Combust. Sci. 25:595.
14. Kronenburg, A., R. W. Bilger, and J. H. Kent. 2000. Computation of conditional average scalar dissipation in turbulent jet diffusion flames. Flow, Turbulence and Combustion 64:145.
15. Lentini, D. 1994. Assessment of the stretched laminar flamelet approach for nonpremixed turbulent combustion. Combustion Science and Technology 100:95.
16. Libby, P. A., and F. A. Williams, editors. 1994. Turbulent Reacting Flows, New York: Academic Press.
17. Lutz, A., R. J. Kee, J. F. Grcar, and F. M. Rupley. 1996. OPPDIF: A Fortran Program for Computing Opposed-Flow Diffusion Flames, Sandia Report, SAND96-8243, Livermore.
18. Marracino, B., and D. Lentini. 1997. Radiation modelling in non-luminous nonpremixed turbulent flames. Combustion Science and Technology 128:23.
19. Peters, N. 1986. Laminar flamelet concepts in turbulent combustion, Proc. 21st Symp. (Int.) Comb., Pittsburgh, PA: Combustion Institute, 1231.
20. Peters, N. 2000. Turbulent Combustion, Cambridge, MA: Cambridge University Press.
21. Pitsch, H. 2000. Unsteady flamelet modeling of differential diffusion in turbulent jet diffusion flames. Combustion and Flame 123:358.
22. Pitsch, H., H. Barths, and N. Peters. 1996. Three-dimensional modeling of NOx and soot formation in DI-diesel engines using detailed chemistry based on the interactive flamelet approach. SAE Paper 962057.
23. Pitsch, H., M. Chen, and N. Peters. 1998. Unsteady flamelet modeling of turbulent hydrogen-air diffusion flames. Proc. 27th Symp. (Int.) Comb., Pittsburgh, PA: Combustion Institute, 1057.
24. Pitsch, H., and N. Peters. 1998. A consistent flamelet formulation for non-premixed combustion considering differential diffusion effects. Combustion and Flame 114:26.
25. Pitsch, H., E. Riesmeier, and N. Peters. 2000. Unsteady flamelet modeling of soot formation in turbulent jet diffusion flames. Combustion Science and Technology 158:389.
26. Pitsch, H., and H. Steiner. 2000. Large-eddy simulation of a turbulent piloted methane/air diffusion flame (Sandia flame D). Physics of Fluids 12:2541.
27. Pope, S. B. 1978. An explanation of the turbulent round jet/plane jet anomaly. AIAA Journal 16:301.
28. Pope, S. B. 2000. Turbulent Flows, Cambridge, MA: Cambridge University Press.
29. Radhakrishnan, K., and A. C. Hindmarsh. 1993. Description and use of LSODE, the livermore solver for ordinary differential equations. Lawrence Livermore National Laboratory Report, UCRL-ID-113855.
30. Seshadri, K., and N. Peters. 1988. Asymptotic structure and extinction of methane-air diffusion flame. Combustion and Flame 73:23-44.
31. Vervisch, L., and D. Veynante. 2001. Turbulent combustion modeling, submitted to Prog. Energy Combust. Sci.
32. Warnatz, J., U. Maas, and R. W. Dibble. 1996. Combustion, Berlin, Germany: Springer-Verlag.