Using virtual engineering tools to reduce NOx emissions

American Society of Mechanical Engineers, Power Division (Publication) PWR

Volumn 35, Issue , 2004, Pages 441-446

  McCorkle, Douglas S ^a   Bryden, Kenneth M ^a   Swensen, David A ^b  

^a Iowa State University of Science and Technology   (United States)

^b REACTION ENGINEERING INTERNATIONAL   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

COMPUTATIONAL METHODS; COMPUTER SIMULATION; GAS EMISSIONS; HEAT TRANSFER; NITROGEN OXIDES; OPTIMIZATION; VIRTUAL REALITY; COMPUTATIONAL FLUID DYNAMICS; COMPUTATIONAL GEOMETRY; DESIGN; ENGINEERS; POWER PLANTS; REDUCTION; SOFTWARE ARCHITECTURE;

EMISSION REDUCTIONS; OFF-LINE PROCESSES; THERMAL FLUIDS; VIRTUAL ENGINEERING; CFD SOLVER; COMPUTATIONAL MODEL; COMPUTATIONAL RESOURCES; DATA SETS; OPTIMIZATION ROUTINE; POWER PLANT SYSTEM; SYSTEM GEOMETRY;

COMPUTATIONAL FLUID DYNAMICS; MODELS;

EID: 2942536106     PISSN: None     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1115/power2004-52021     Document Type: Conference Paper

References (4)

1. M. J. Bockelie, B. R. Adams, M. A. Cremer, K. A. Davis, E. G. Eddings, J. R. Valentine, P. J. Smith, M. P. Heap, 1998, "Computational simulations of industrial furnaces," ASME Pressure Vessels Piping Div Publ PVP, v377, n2, pp. 117-124.
2. L. D. Smoot, P. J. Smith, 1985, "Coal Combustion and Gasification," Plenum Press, NY, NY.
3. Adams, B.R., et al, eds., 1995, "Technical Overview of Reaction Engineering International Combustion Simulation Software," Reaction Engineering International, SLC, UT.
4. S. V. Patankar, 1980, "Numerical Heat Transfer and Fluid Flaw," Taylor and Francis, Levittown, PA.