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Combustion Science and Technology Volume 184, 2012 - Issue 5
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Original Articles

Transported PDF Modeling of Nonpremixed Turbulent CO/H2/N2 Jet Flames

Xinyu Zhao National Energy Technology Laboratory–Regional University Alliance (NETL-RUA), Morgantown, West Virginia, USA; Department of Mechanical & Nuclear Engineering, The Pennsylvania State University, University Park, Pennsylvania, USACorrespondence[email protected]
,
D. C. Haworth National Energy Technology Laboratory–Regional University Alliance (NETL-RUA), Morgantown, West Virginia, USA; Department of Mechanical & Nuclear Engineering, The Pennsylvania State University, University Park, Pennsylvania, USA
&
E. David Huckaby U.S. Department of Energy–National Energy Technology Laboratory, Morgantown, West Virginia, USA
Pages 676-693 | Received 26 Sep 2011, Accepted 19 Jan 2012, Published online: 14 May 2012

REFERENCES

  • Abián , M. , Giménez-López , J. , Bilbao , R. , and Alzueta , M.U. 2011 . Effect of different concentration levels of CO2 and H2O on the oxidation of CO: Experiments and modeling . Proc. Combust. Inst. , 33 , 317 – 323 .
  • Barlow , R.S. 2011. Intern'l. Workshop on Measurement and Computation of Turbulent Non-premixed Flames , Combustion Research Facility, Sandia National Laboratories , Livermore , CA; http://www.ca.sandia.gov/TNF/
  • Barlow , R.S. , Fiechtner , G.J. , Carter , C.D. , and Chen , J.Y. 2000 . Experiments on the scalar structure of turbulent CO/H2/N2 jet flames . Combust. Flame , 120 , 549 – 569 .
  • Bowman , C.T. , Hanson , R.K. , Davidson , D.F. , Gardiner , W.C. , Lissianski , V. , Smith , G.P. , Golden , D.M. , Frenklach , M. , and Goldenberg , M. 1995 . GRI-Mech 2.11 ; Available at http://www.me.berkeley.edu/gri_mech
  • Buhre , B.J.P. , Elliott , L.K. , Sheng , C.D. , Gupta , R.P. , and Wall , T.F. 2005 . Oxy-fuel combustion technology for coal-fired power generation . Prog. Energy Combust. Sci. , 31 , 283 – 307 .
  • Chen , J.Y. 2011 . http://www.sandia.gov/TNF/chemistry.html
  • Chen , J.Y. , Dibble , W. , and Bilger , R.W. 1991 . PDF modeling of turbulent nonpremixed CO/H2/N2 jet flames with reduced mechanism . Proc. Combust. Inst. , 23 , 775 – 780 .
  • Correa , S.M. , Drake , M.C. , Pitz , R.W. , and Shyy , W. 1985 . Prediction and measurement of a non-equilibrium turbulent diffusion flame . Proc. Combust. Inst. , 20 , 337 – 343 .
  • Correa , S.M. , Gulati , A. , and Pope , S.B. 1988 . Assessment of a partial-equilibrium/Monte Carlo model for turbulent syngas flames . Combust. Flame , 72 , 159 – 173 .
  • Cuoci , A. , Frassoldati , A. , Ferraris , G.B. , Faravelli , T. , and Ranzi , E. 2007 . The ignition, combustion and flame structure of carbon monoxide/hydrogen mixtures, Note 2: Fluid dynamics and kinetic aspects of syngas combustion . Int. J. Hydrogen Energy , 32 , 3486 – 3500 .
  • Curl , R.L. 1963 . Dispersed phase mixing: I. Theory and effects in simple reactors . AIChE J. , 9 , 175 – 181 .
  • Dryer , F.L. 2011 . Princeton University , Personnal communication .
  • Fox , R.O. 2003 . Computational Models for Turbulent Reacting Flows , Cambridge University Press , Cambridge , UK .
  • Frank , J.H. , Barlow , R.S. , and Lundquist , C. 2000 . Radiation and nitric oxide formation in turbulent non-premixed jet flames . Proc. Combust. Inst. , 28 , 447 – 454 .
  • Frassoldati , A. , Faravelli , T. , and Ranzi , E. 2007 . The ignition, combustion and flame structure of carbon monoxide/hydrogen mixtures, Note 1: Detailed kinetic modeling of syngas combustion also in presence of nitrogen compounds . Int. J. Hydrogen Energy , 32 , 3471 – 3485 .
  • Giacomazzi , E. , Picchia , F.R. , Arcidiacono , N. , and Cecere , D. 2006 . Numerical simulation of turbulent combustion on CRESCO platform . Final Workshop of Grid Projects, “PON RICERCA 2000–2006, AV VISO 1575.”
  • Giacomazzi , E. , Picchia , F.R. , Cecere , D. , and Arcidiacono , N. 2008 . Unsteady simulation of a CO/H2/N2 air turbulent non-premixed flame . Combust. Theor. Model. , 12 , 1125 – 1152 .
  • Haworth , D.C. 2010 . Progress in probability density function methods for turbulent reacting flows . Prog. Energy Combust. Sci. , 36 , 168 – 259 .
  • Haworth , D.C. , Drake , M.C. , and Blint , R.J. 1988 . Stretched laminar flamelet modeling of a turbulent jet diffusion flame . Combust. Sci. Technol. , 60 , 287 – 318 .
  • Haworth , D.C. , Drake , M.C. , Pope , S.B. , and Blint , R.J. 1989 . The importance of time-dependent flame structures in stretched laminar flamelet models for turbulent jet diffusion flames . Proc. Combust. Inst. , 22 , 589 – 597 .
  • Hewson , J.C. , and Kerstein , A.R. 2001 . Stochastic simulation of transport and chemical kinetics in turbulent CO/H2/N2 flames . Combust. Theor. Model. , 5 , 669 – 697 .
  • Jaishree , J. , and Haworth , D.C. 2012 . Comparisons of Lagrangian and Eulerian PDF methods in simulations of nonpremixed turbulent jet flames with moderate-to-strong turbulence-chemistry interactions . Combust. Theor. Model. , 16 ( 3 ), 435 – 463 .
  • James , S. , Anand , M.S. , Razdan , M.K. , and Pope , S.B. 2001. In situ detailed chemistry calculations in combustor flow analyses. J. Eng. Gas Turbines Power , 123, 747–756.
  • Kim , S.K. , Kang , S.M. , and Kim , Y.M. 2001 . Flamelet modeling for combustion processes and NOx formation in the turbulent nonpremixed CO/H2/N2 jet flames . Combust. Sci. Technol. , 168 , 47 – 83 .
  • Li , J. , Zhao , Z. , Kazakov , A. , Chaos , M. , Dryer , F.L. , and Scire , J.J. 2007 . A comprehensive kinetic mechanism for CO, CH2O, CH3OH combustion . Int. J. Chem. Kinet. , 39 , 109 – 136 .
  • Lu , L. , and Pope , S.B. 2009 . An improved algorithm for in situ adaptive tabulation . J. Comput. Phys. , 228 , 361 – 386 .
  • Masri , A.R. , Subramaniam , S. , and Pope , S.B. 1996 . A mixing model to improve the PDF simulation of turbulent diffusion flames . Proc. Combust. Inst. , 26 , 49 – 57 .
  • Mehta , R.S. , Haworth , D.C. , and Modest , M.F. 2010 . Composition PDF/photon Monte Carlo modeling of moderately sooting turbulent jet flames . Combust. Flame , 157 , 982 – 994 .
  • Muradoglu , M. , Jenny , P. , Pope , S.B. , and Caughey , D.A. 1999 . A consistent hybrid finite volume/particle method for the PDF equations of turbulent reactive flows . J. Comput. Phys. , 154 , 342 – 371 .
  • Muradoglu , M. , Pope , S.B. , and Caughey , D.A. 2001 . The hybrid method for the PDF equations of turbulent reactive flows: Consistency conditions and correction algorithms . J. Comput. Phys. , 172 , 841 – 878 .
  • Nooren , P.A. , Wouters , H.A. , Peeters , T.W.J. , Roekaerts , D. , Maas , U. , and Schmidt , D. 1997 . Monte Carlo PDF modeling of a turbulent natural-gas diffusion flame . Combust. Theor. Model. 1 , 79 – 96 .
  • OpenFOAM . 2011 . http://www.openfoam.com
  • Pope , S.B. 1985 . PDF methods for turbulent reactive flows . Prog. Energy Combust. Sci. , 11 , 119 – 192 .
  • Pope , S.B. , and Correa , S.M. 1987 . Joint PDF calculation of a non-equilibrium turbulent diffusion flame . Proc. Combust. Inst. , 21 , 1341 – 1348 .
  • Smith , N. , Gore , J. , Kim , J. , and Tang , Q. 2011 . Intern'l. Workshop on Measurement and Computation of Turbulent Nonpremixed Flames: Radiation models , Combustion Research Facility, Sandia National Laboratories , Livermore , CA ; http://www.ca.sandia.gov/TNF/radiation.html
  • Subramaniam , S. , and Pope , S.B. 1998 . A mixing model for turbulent reactive flows based on Euclidean minimum spanning trees . Combust. Flame , 115 , 487 – 514 .
  • Viswanathan , S. , Wang , H. , and Pope , S.B. 2011 . Numerical implementation of mixing and molecular transport in LES/PDF studies of turbulent reacting flows . J. Comput. Phys. , 230 , 6916 – 6957 .
  • Wang , A. , and Modest , M.F. 2006 . Photon Monte Carlo simulation for radiative transfer in gaseous media represented by discrete particle fields . J. Heat Transfer , 128 , 1041 – 1049 .
  • Zahirovic , S. , Scharler , R. , Kilpinen , P. , and Obernberger , I. 2001 . Validation of flow simulation and gas combustion sub-models for the CFD-based prediction of NOx formation in biomass grate furnaces . Combust. Theor. Model. , 5 , 669 – 697 .
  • Zahirovic , S. , Scharler , R. , and Obernberger , I. 2006 . Advanced gas phase combustion models: Validation for biogases by means of LES and experiments as well as application to biomass furnaces. Presented at the 7th European Conference on Industrial Furnaces and Boilers, April 18–21, Porto, Portugal.
  • Zsely , I.G. , Zador , J. , and Turanyi , T. 2005 . Uncertainty analysis of updated hydrogen and carbon monoxide mechanisms . Proc. Combust. Inst. 30 , 1273 – 1281 .

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