Etude de la combustion de gaz de synthèse issus d'un processus de ...
Etude de la combustion de gaz de synthèse issus d'un processus de ... Etude de la combustion de gaz de synthèse issus d'un processus de ...
References tel-00623090, version 1 - 13 Sep 2011 14. Bradley D., Lau A.K.C., Lawes M. Flame stretch rate as a determinant of turbulent burning velocity. Philosophical Transactions of the Real Society of London A338, 359-387 (1992). 15. Bradley D., Harper C.M. The development of instabilities in laminar explosion flames. Combustion and Flame 99, 562-572 (1994). 16. Bradley D., Gaskell P.H., Gu X.J. Burning Velocities, Markstein Lengths, and Flame Quenching for Spherical Methane- Air Flames: A computational Study. Combustion and Flame 104 (1 –2), 176 –198 (1996). 17. Bradley D., Hicks R.A., Lawes M., Sheppard C.G.W., Wooley R. The Measurement of Laminar Burning Velocities and Markstein Numbers for Isooctane-Air and iso-octane-n-heptane-Air mixtures at elevated temperatures and pressures in an Explosion bomb. Combustion and Flame 115 (1–2), 126–144 (1998). 18. Bradley D., Lawes M., Kexin L., Verhelst S., Woolley R. Laminar burning velocities of lean hydrogen–air mixtures at pressures up to 1.0 MPa. Combustion and Flame 149, 162-172 (2007). 19. Brander J.A., Chase D.L. Repowering application considerations. Trans. ASME A.J. Eng. Gas Turb. Power 114, 643-652 (1992). 20. Brett L., Macnamara J., Musch P., Simmie J.M. Simulation of methane autoignition in a rapid compression machine with creviced pistons. Combustion and Flame 124, 326-329 (2001). 21. Bridgwater A.V., Evans G.D. An Assessment of Thermochemical Conversion Systems for Processing Biomass and Refuse. Energy Technology Support Unit (ETSU) on behalf of the Department of Trade, ETSU B/T1/00207/REP, 1993. 22. Bridgwater A.V. The technical and economic feasibility of biomass gasification for power generation. Fuel 74 (5), 631-653 (1995). 23. Bridgwater AV. Towards the ‘bio-refinery’ fast pyrolysis of biomass. Renewable Energy World, James & James, London Vol. 4, (1), 66-83 (2001). 24. Bridgwater A.V., Toft A.J., Brammer J.G. A Techno-economic comparison of power production by biomass fast pyrolysis with gasification and combustion. Journal of Renewable & Sustainable Energy Reviews, 181-248 (2002). 25. Bridgwater A.V. Renewable fuels and chemicals by thermal processing of biomass. Chemical Engineering Journal 91, 87–102 (2003). 26. Brown M.J., McLean I.C., Smith D.B., Taylor S.C. Markstein lengths of CO/H 2 /Air flames, using expanding spherical flames. Proceedings of the Combustion Institute 26, 875-881 (1996). 202
References tel-00623090, version 1 - 13 Sep 2011 27. Buckmaster J. Slowly varying laminar flames. Combustion and Flame 28, 225- 239 (1977). 28. Burke M.P., Qin X., Ju Y., Dryer F.L. Measurements of hydrogen syngas flame speeds at elevated pressures. 5 th US Combustion Meeting, March 25–28, 2007. 29. Candel S.M., Poinsot T.J. Flame Stretch and the Balance Equation for the Flame Area. Combustion Science Technology 70, 1-15 (1990). 30. Carpentieri M., Corti A., Lombardi L. Life cycle assessment (LCA) of an integrated biomass gasification combined cycle (IBGCC) with CO 2 removal. Journal of Energy Conversion and Management 46, 1790–1808 (2005). 31. Ciferno J.P., Marano J.J. Benchmarking Biomass Gasification Technologies for Fuels, Chemicals and Hydrogen Production. U.S. Department of Energy, National Energy Technology Laboratory, 2002. 32. Chiodi M., Bargende M. Improvement of Engine Heat-Transfer Calculation in the Three-Dimensional Simulation Using a Phenomenological Heat-Transfer Model. SAE Technical Paper 2001-01-3601 (2001). 33. Chomiak J. Combustion: A study in Theory, Fact and Application (Energy and Engineering Science Series). Gordon and Breach Science Publishers, 1990. 34. Chung S.H., Law C.K. An Integral Analysis of the Structure and Propagation of Stretched Premixed Flames. Combustion and Flame 72, 325-336 (1988). 35. Clarkson J., Griffiths J.F., Macnamara J.P., Whitaker B.J. Temperature fields during the development of combustion in a rapid compression machine. Combustion and Flame 125, 1162-1175 (2001). 36. Clavin P., Williams F.A. Effects of molecular diffusion and of thermal expansion on the structure and dynamics of premixed flames in turbulent flows of large scale and low intensity. J. Fluid Mechanics 116, 251-282 (1982). 37. Clavin. P. Dynamic behavior of premixed flame fronts in laminar and turbulent flows. Progress in Energy Combustion Sciences 11, 1-59 (1985). 38. Clavin P., Joulin G. Flamelet library for turbulent wrinkled flames. Lecture Notes in Engineering:Turbulent Reactive Flows 40, 213–239 (1989). 39. Coppens F.H.V., Ruyck J., Konnov A. The effects of composition on burning velocity and nitric oxide formation in laminar premixed flames of CH 4 +H 2 +O 2 +N 2 . Combustion and Flame 149, 409-417 (2007). 40. Coward H.F., Hartwell F.J. Studies in the mechanism of flame movement. Part II. The fundamental speed of flame in mixtures of methane and air. J. Chem. Soc. 2672-2874 (1932). 41. Coward H. F., Payman W. Problems in flame propagation. Chemical Reviews 21 (3), 359-366 (1937). 203
- Page 157 and 158: Chapter 5 tel-00623090, version 1 -
- Page 159 and 160: Chapter 5 From figure 5.15 is possi
- Page 161 and 162: Chapter 5 From figure 5.16 is obser
- Page 163 and 164: Chapter 5 80 Pressure (bar) 70 60 5
- Page 165 and 166: Chapter 5 80 10 Pmax (bar) 70 60 50
- Page 167 and 168: Chapter 5 -5.0 ms -3.75 ms -2.5 ms
- Page 169 and 170: Chapter 5 observation emphasis the
- Page 171 and 172: Chapter 6 CHAPTER 6 NUMERICAL SIMUL
- Page 173 and 174: Chapter 6 centered at the spark plu
- Page 175 and 176: Chapter 6 H 2 O, (3) N 2 , (4) O 2
- Page 177 and 178: Chapter 6 For all the above express
- Page 179 and 180: Chapter 6 motions within the cylind
- Page 181 and 182: Chapter 6 tel-00623090, version 1 -
- Page 183 and 184: Chapter 6 Heat transfer Wei et al.,
- Page 185 and 186: Chapter 6 The calibration coefficie
- Page 187 and 188: Chapter 6 6.3.2.2 In-cylinder volum
- Page 189 and 190: Chapter 6 40 Experimental 30 Numeri
- Page 191 and 192: Chapter 6 80 70 60 Numerical Experi
- Page 193 and 194: Chapter 6 downdraft syngas than for
- Page 195 and 196: Chapter 6 80 23º BTDC 60 29.5º BT
- Page 197 and 198: Chapter 6 with experimental results
- Page 199 and 200: Conclusions CHAPTER 7 CONCLUSIONS 7
- Page 201 and 202: Conclusions radius and time for syn
- Page 203 and 204: Conclusions conditions, therefore s
- Page 205 and 206: Conclusions tel-00623090, version 1
- Page 207: References References tel-00623090,
- Page 211 and 212: References tel-00623090, version 1
- Page 213 and 214: References tel-00623090, version 1
- Page 215 and 216: References tel-00623090, version 1
- Page 217 and 218: References tel-00623090, version 1
- Page 219 and 220: References tel-00623090, version 1
- Page 221 and 222: Appendix A - Overdetermined linear
- Page 223 and 224: Appendix A - Overdetermined linear
- Page 225 and 226: Appendix B- Syngas-air mixtures pro
- Page 227 and 228: Appendix C -Rivère model Heat flux
- Page 229 and 230: Appendix C -Rivère model The work
- Page 231 and 232: tel-00623090, version 1 - 13 Sep 20
References<br />
tel-00623090, version 1 - 13 Sep 2011<br />
14. Bradley D., Lau A.K.C., Lawes M. F<strong>la</strong>me stretch rate as a <strong>de</strong>terminant of<br />
turbulent burning velocity. Philosophical Transactions of the Real Society of<br />
London A338, 359-387 (1992).<br />
15. Bradley D., Harper C.M. The <strong>de</strong>velopment of instabilities in <strong>la</strong>minar explosion<br />
f<strong>la</strong>mes. Combustion and F<strong>la</strong>me 99, 562-572 (1994).<br />
16. Bradley D., Gaskell P.H., Gu X.J. Burning Velocities, Markstein Lengths, and<br />
F<strong>la</strong>me Quenching for Spherical Methane- Air F<strong>la</strong>mes: A computational Study.<br />
Combustion and F<strong>la</strong>me 104 (1 –2), 176 –198 (1996).<br />
17. Bradley D., Hicks R.A., Lawes M., Sheppard C.G.W., Wooley R. The<br />
Measurement of Laminar Burning Velocities and Markstein Numbers for Isooctane-Air<br />
and iso-octane-n-heptane-Air mixtures at elevated temperatures and<br />
pressures in an Explosion bomb. Combustion and F<strong>la</strong>me 115 (1–2), 126–144<br />
(1998).<br />
18. Bradley D., Lawes M., Kexin L., Verhelst S., Woolley R. Laminar burning<br />
velocities of lean hydrogen–air mixtures at pressures up to 1.0 MPa. Combustion<br />
and F<strong>la</strong>me 149, 162-172 (2007).<br />
19. Bran<strong>de</strong>r J.A., Chase D.L. Repowering application consi<strong>de</strong>rations. Trans. ASME<br />
A.J. Eng. Gas Turb. Power 114, 643-652 (1992).<br />
20. Brett L., Macnamara J., Musch P., Simmie J.M. Simu<strong>la</strong>tion of methane<br />
autoignition in a rapid compression machine with creviced pistons. Combustion<br />
and F<strong>la</strong>me 124, 326-329 (2001).<br />
21. Bridgwater A.V., Evans G.D. An Assessment of Thermochemical Conversion<br />
Systems for Processing Biomass and Refuse. Energy Technology Support Unit<br />
(ETSU) on behalf of the Department of Tra<strong>de</strong>, ETSU B/T1/00207/REP, 1993.<br />
22. Bridgwater A.V. The technical and economic feasibility of biomass gasification for<br />
power generation. Fuel 74 (5), 631-653 (1995).<br />
23. Bridgwater AV. Towards the ‘bio-refinery’ fast pyrolysis of biomass. Renewable<br />
Energy World, James & James, London Vol. 4, (1), 66-83 (2001).<br />
24. Bridgwater A.V., Toft A.J., Brammer J.G. A Techno-economic comparison of<br />
power production by biomass fast pyrolysis with gasification and <strong>combustion</strong>.<br />
Journal of Renewable & Sustainable Energy Reviews, 181-248 (2002).<br />
25. Bridgwater A.V. Renewable fuels and chemicals by thermal processing of<br />
biomass. Chemical Engineering Journal 91, 87–102 (2003).<br />
26. Brown M.J., McLean I.C., Smith D.B., Taylor S.C. Markstein lengths of CO/H 2 /Air<br />
f<strong>la</strong>mes, using expanding spherical f<strong>la</strong>mes. Proceedings of the Combustion<br />
Institute 26, 875-881 (1996).<br />
202
Change language