numerical modelling of auto - FSB - SveuÄiliÅ¡te u Zagrebu

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ReferencesEvaporation Device Operating in the “Stabilized Cool Flame” regime," inSeventh International Conference on CFD in the Minerals and ProcessIndustries Proceedings, 2009.[86] A.A. Pekalski. et al., "The relation of cool flames and auto-ignitionphenomena to process safety at elevated pressure and temperature," Journalof Hazardous Materials, vol. 93, pp. 93-105, 2002.[87] H. Pearlman, "Multiple cool flames in static, unstirred reactors underreduced-gravity and terrestrial conditions," Combustion and Flame, vol. 148,pp. 280-284, 2007.[88] S. Tanaka, F. Ayala, and J. C. Keck, "A reduced chemical kinetic model forHCCI combustion of primary reference fuel in a rapid compressio machine,"Combustion and Flame, vol. 133, pp. 467-481, 2003.[89] N. Peters, G. Paczko, R. Seiser, and K. Seshadri, "Temperature Cross-Overand Non-Thermal Runaway at Two-Stage Ignition of NHeptane,"Combustion and Flame, vol. 128, no. 1-2, pp. 38-59 , 2002.[90] M. Valorani, F. Creta, F. Donato, H. N. Najm, and D. A. Goussis, "Skeletalmechanism generation and analysis for n-heptane with CSP," Proceedings ofthe Combustion Institute, vol. 31, no. 1, pp. 483-490, 2007.[91] B. Bhattacharjee, D. Schwer, P. Barton, and W. Green, "Optimally-reducedkinetic models: reaction elimination in large-scale kinetic mechanisms,"Combustion and Flame , vol. 135, no. 3, pp. 191-208, 2003.[92] T. Lu and C. Law, "A directed relation graph method for mechanismreduction," Proceedings of the Combustion Institute, vol. 30, no. 1, pp. 1333-1341, 2005.[93] P. Pepiot and H. Pitsch, "Systematic reduction of large chemicalmechanism," in Proceedings of the 4th Joint Meeting of the US Sections ofthe Combustion Institute, 2005.[94] M. Hamdi, H. Benticha, and M. Sassi, "Evaluation of Reduced Chemical132
ReferencesKinetic Mechanisms Used for Modelling Mild Combustion for Natural Gas,"Thermal Science , vol. 13, no. 3, pp. 131-137, 2009.[95] R. Ennetta, M. Hamdi, and R. Said, "Comparison of Different ChemicalKinetic Mechanisms of Methane Combustion in an Internal CombustionEngine Configuration," Thermal Science , vol. 12, no. 1, pp. 43-51, 2008.[96] S.S. Ahmed, F. Mauss, G. Moréac, and T. Zeuch, "A comprehensive andcompact n-heptane oxidation model derived using chemical lumping,"Physical Chemistry Chemical Physics, vol. 9, pp. 1107-1126, 2007.[97] J. C. Hewson. (1997) Pollutant Emissions from Nonpremixed HydrocarbonFlames. Doctoral dissertation.[98] H. Seiser, Pitsch H., Seshadri K., Pitz W.J., and Curran H.J., "Extinction andAutoignition of n- Heptane in Counterflow Configuration," Proceedings of theCombustion Institute, vol. 28, pp. 2029-2037, 2000.[99] S. Liu, J.C. Hewson, J. H. Chen, and H. Pitsch, "Effects on Strain Rate onHigh-Pressure Nonpremixed N-Heptane Autoignition in Counterflow,"Combustion and Flame, vol. 137, pp. 320-339, 2004.[100] S. Jerzembeck, N. Peters, P. Pepiot-Desjardins, and H. Pitsch, "LaminarBurning Velocities at High Pressure for Primary Reference Fuels andGasoline: Experimental and Numerical Investigation," Combustion andFlame, vol. 156, no. 2, pp. 292-301, 2009.[101] P. Pepiot-Desjardins and H. Pitsch, "An automatic chemical lumping methodfor the reduction of large chemical kinetic mechanisms," Combustion TheoryAnd Modelling, vol. 12, no. 6, pp. 1089-1108, 2008.[102] J. Andrae, D. Johansson, P. Björnbom, P. Risberg, and G. Kalghatgi, "Cooxidationin the auto-ignition of primary reference fuels and n-heptane/toluene blends," Combustion and Flame, vol. 140, no. 4, pp. 267-286 , 2005.[103] K. Natarajan and KA. Bhaskaran, "An experimental and analytical133
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BIBLIOGRAPHY DATA:UDC: -Keywords:Co
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Prediction is very difficult, espec
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2.7 Flame velocity ................
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PrefaceEnergy crisis we are facing
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SažetakGlavna namjera istraživanj
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uređaja. Da bi se što vjernije si
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pokušavaju što je više pojednost
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Kao grubo pravilo postavljeno uzeta
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tabelirane vrijednosti oslobođene
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List of figuresFigure 2-1 Ignition
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List of tablesTable 2-1 Diesel fuel
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k Thermal conductiv ity W/(mK)Turbu
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EGRresidual gasesfforward (in react
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NTCODEPDFPFRANSRONTDCTKINegative Te
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IntroductionWhen one considers the
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Introductionpopular mechanism for l
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Introductioninitially developed in
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Introductionclassical Diesel engine
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Introductionadvancement of reaction
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Introductionmechanisms using Arrhen
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Introductionused, or the complexity
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Methodologyh+o2 = o+oh 1.915E+14 0.
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Methodologygiving the temperature d
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Methodologywith the mean specific h
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Methodology3500T = 800 K / p = 40 b
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Methodologyignition data to databas
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Methodology1,00E+001,00E-01Ignition
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MethodologyOn the above figure, met
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Methodology1,60E-019,00E-011,40E-01
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MethodologyṀdTdx − 1 d dTλAc p
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Methodologyspecies was solved by ru
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Methodology“optimal” value, fin
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Methodologythe performance in some
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MethodologyCopper corrosion - Class
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MethodologyWhen studying the comple
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Methodologycounter-flow case [99].
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Methodologycomplexity (directly cor
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Methodologymechanism (since the mec
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Methodologycombustion systems at th
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Methodology2.10.5 MethaneMethane as
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Methodology2,90E+032,70E+032,50E+03
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MethodologyThe mechanism described
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Methodologyshell script, can also b
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Methodologyn O2= O stoich1φ , (2-2
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Methodologywas first used for autoi
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Methodologyinvestigating the result
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MethodologyThe parameters in the ab
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Methodologybased on a penalized lea
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Methodologyon equivalence ratio). T
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Methodology0composition) and S L re
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MethodologyThe parameter values for
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Methodology0,00090,00080,0007igniti
Page 112 and 113: Methodology2.12 CFD ModellingEven i
Page 114 and 115: Methodologytime rate of change of m
Page 116 and 117: MethodologyThe integral form of the
Page 118 and 119: MethodologyAgain, to transform the
Page 120 and 121: Methodologylaminar exchange coeffic
Page 122 and 123: MethodologyC ζ μ = 0.22, C ε1 =
Page 124 and 125: MethodologyThe zones as defined abo
Page 126 and 127: Methodology∂ρ̅YuF∂t+ ∂ρ̅Y
Page 128 and 129: Methodology∂Σρ̅∂t + ∂Σρ
Page 130 and 131: Methodology2.13.2 Ignition Modellin
Page 132 and 133: MethodologyFigure 2-21 Temporal evo
Page 134 and 135: Numerical Simulations and Results3
Page 136 and 137: Numerical Simulations and ResultsEq
Page 138 and 139: Numerical Simulations and Resultsgo
Page 140 and 141: Numerical Simulations and Resultsre
Page 142 and 143: Numerical Simulations and Results3.
Page 144 and 145: Numerical Simulations and Resultsfo
Page 146 and 147: Numerical Simulations and ResultsFi
Page 148 and 149: Numerical Simulations and ResultsFi
Page 150 and 151: Conclusion4 ConclusionTo accurately
Page 152 and 153: Conclusionchemical mechanism and ac
Page 154 and 155: References[11] T. Rente, V. I. Golo
Page 156 and 157: References465-472, 2007.[29] B. Fio
Page 158 and 159: ReferencesHydrogen-Air Diffusion Fl
Page 160 and 161: ReferencesAnalysis," Sandia Nationa
Page 164 and 165: Referencesinvestigation of high tem
Page 166 and 167: Referencessimulation of turbulent f
Page 168 and 169: Curriculum VitaeCurriculum VitaeNam
Page 170: Curriculum VitaePoslijediplomskistu
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