參考文獻 |
[1] International Energy Agency, Energy technology perspectives 2017: Catalysing energy technology transformations, 2017. https://doi.org/10.1787/energy_tech-2017-en
[2] Y. Ju, W. Sun, Plasma assisted combustion: Dynamics and chemistry, Prog. Energy Combust. Sci. 48 (2015) 21-83.
[3] K. Maruta, H. Nakamura, Super lean-burn in SI engine and fundamental combustion studies, J. Combust. SOC. Japan 58 (2016) 9-19.
[4] N. Hayashi, A. Sugiura, Y. Abe, K. Suzuki, Development of ignition technology for dilute combustion engines, SAE Int. J. Engines 10 (2017) 984-995.
[5] K. Nakata, S. Nogawa, D. Takahashi, Y. Yoshihara, et al., Engine technologies for achieving 45% thermal efficiency of S.I. engine, SAE Int. J. Engines 9 (2015) 179-192.
[6] B. Lewis, G. von Elbe, Combustion, Flames and Explosions of Gases, 3rd ed., Academic Press, Orlando, 1987.
[7] L.J. Jiang, S. Shy, M.T. Nguyen, S.Y. Huang, D.W. Yu, Spark ignition probability and minimum ignition energy transition of the lean iso-octane/air mixture in premixed turbulent combustion, Combust. Flame 187 (2018) 87-95.
[8] D. Jung, N. Iida, An investigation of multiple spark discharge using multi-coil ignition system for improving thermal efficiency of lean SI engine operation, Appl Energy 212 (2018) 322-332.
[9] S. Tsuboi, S. Miyokawa, M. Matsuda, T. Yokomori, N. Iida, Influence of spark discharge characteristics on ignition and combustion process and the lean operation limit in a spark ignition engine, Appl Energy 250 (2019) 617-632.
[10] J. Moorhouse, A. Williams, T.E. Maddison, An investigation of the minimum ignition energies of some C1 to C7 hydrocarbons, Combust. Flame 23 (1974) 203-213.
[11] D.R. Ballal, A.H. Lefebvre, The influence of flow parameters on minimum ignition energy and quenching distance, Symp. Int. Combust. 15 (1975) 1473-1481.
[12] R. Maly, M. Vogel, Initiation and propagation of flame fronts in lean CH4-air mixtures by the three modes of the ignition spark, Symp. Int. Combust. 17 (1979) 821-831.
[13] M. Kono, K. Hatori, K. Iinuma, Investigation on ignition ability of composite sparks in flowing mixtures, Symp. Int. Combust. 20 (1985) 133-140.
[14] G.F.W. Ziegler, E.P. Wagner, R.R. Maly, Ignition of lean methane-air mixtures by high pressure glow and ARC discharges, Symp. Int. Combust. 20 (1985) 1817-1824.
[15] D. Bradley, F.K.K. Lung, Spark ignition and the early stages of turbulent flame propagation, Combust. Flame 69 (1987) 71-93.
[16] M. Kono, K. Niu, T. Tsukamoto, Y. Ujiie, Mechanism of flame kernel formation produced by short duration sparks, Symp. Int. Combust. 22 (1989) 1643-1649.
[17] Y. Ko, R.W. Anderson, V.S. Arpaci, Spark ignition of propane-air mixtures near the minimum ignition energy: Part I. An experimental study, Combust. Flame 83 (1991) 75-87.
[18] K. Ishii, O. Aoki, Y. Ujiie, M. Kono, Investigation of ignition by composite sparks under high turbulence intensity conditions, Symp. Int. Combust. 24 (1992) 1793-1798.
[19] T. Kravchik, E. Sher, J.B. Heywood, From spark ignition to flame initiation, Combust. Sci. Technol. 108 (1995) 1-30.
[20] C.F. Kaminski, J. Hult, M. Aldén, S. Lindenmaier, et al., Spark ignition of turbulent methane/air mixtures revealed by time-resolved planar laser-induced fluorescence and direct numerical simulations, Proc. Combust. Inst. 28 (2000) 399-405.
[21] T. Horstmann, W. Leuckel, B. Maurer, U. Maas, Influence of turbulent flow conditions on the ignition of flammable gas/air mixtures, Process Saf. Prog. 20 (2001) 215-224.
[22] C.C. Huang, S.S. Shy, C.C. Liu, Y.Y. Yan, A transition on minimum ignition energy for lean turbulent methane combustion in flamelet and distributed regimes, Proc. Combust. Inst. 31 (2007) 1401-1409.
[23] S.S. Shy, W.T. Shih, C.C. Liu, More on minimum ignition energy transition for lean premixed turbulent methane combustion in flamelet and distributed regimes, Combust. Sci. Technol. 180 (2008) 1735-1747.
[24] S.S. Shy, C.C. Liu, W.T. Shih, Ignition transition in turbulent premixed combustion, Combust. Flame 157 (2010) 341-350.
[25] S.P.M. Bane, Spark Ignition: Experimental and numerical investigation with aplication to aviation safety, PhD dissertation, California Institute of Technology, 2010. http://thesis.library.caltech.edu/5868/1/thesis_SBane.pdf.
[26] M.W. Peng, S.S. Shy, Y.W. Shiu, C.C. Liu, High pressure ignition kernel development and minimum ignition energy measurements in different regimes of premixed turbulent combustion, Combust. Flame 160 (2013) 1755-1766.
[27] S.S. Shy, Y.W. Shiu, L.J. Jiang, C.C. Liu, S. Minaev, Measurement and scaling of minimum ignition energy transition for spark ignition in intense isotropic turbulence from 1 to 5 atm, Proc. Combust. Inst. 36 (2017) 1785-1791.
[28] R.K. Eckhoff, M. Ngo, W. Olsen, On the minimum ignition energy (MIE) for propane/air, J Hazard Mater 175 (2010) 293-297.
[29] S.P.M. Bane, J.E. Shepherd, E. Kwon, A.C. Day, Statistical analysis of electrostatic spark ignition of lean H2/O2/Ar mixtures, Int. J. Hydrogen Energy 36 (2011) 2344-2350.
[30] S. Coronel, R. Mével, S.P.M. Bane, J.E. Shepherd, Experimental study of minimum ignition energy of lean H2-N2O mixtures, Proc. Combust. Inst. 34 (2013) 895-902.
[31] S.P.M. Bane, J.L. Ziegler, P.A. Boettcher, S.A. Coronel, J.E. Shepherd, Experimental investigation of spark ignition energy in kerosene, hexane, and hydrogen, J. Loss Prevent. Process Ind. 26 (2013) 290-294.
[32] A. Wähner, G. Gramse, T. Langer, M. Beyer, Determination of the minimum ignition energy on the basis of a statistical approach, J. Loss Prevent. Process Ind. 26 (2013) 1655-1660.
[33] S.P.M. Bane, J.L. Ziegler, J.E. Shepherd, Investigation of the effect of electrode geometry on spark ignition, Combust. Flame 162 (2015) 462-469.
[34] K. Ishii, T. Tsukamoto, Y. Ujiie, M. Kono, Analysis of ignition mechanism of combustible mixtures by composite sparks, Combust. Flame 91 (1992) 153-164.
[35] N. Chakraborty, E. Mastorakos, R.S. Cant, Effects of turbulence on spark ignition in inhomogeneous mixtures: A direct numerical simulation (DNS) study, Combust. Sci. Technol. 179 (2007) 293-317.
[36] J. Han, H. Yamashita, N. Hayashi, Numerical study on the spark ignition characteristics of a methane–air mixture using detailed chemical kinetics: Effect of equivalence ratio, electrode gap distance, and electrode radius on MIE, quenching distance, and ignition delay, Combust. Flame 157 (2010) 1414-1421.
[37] J. Han, H. Yamashita, N. Hayashi, Numerical study on the spark ignition characteristics of hydrogen–air mixture using detailed chemical kinetics, Int. J. Hydrogen Energy 36 (2011) 9286-9297.
[38] Z. Chen, M.P. Burke, Y. Ju, On the critical flame radius and minimum ignition energy for spherical flame initiation, Proc. Combust. Inst. 33 (2011) 1219-1226.
[39] E. Sereshchenko, R. Fursenko, S. Minaev, S. Shy, Numerical simulations of premixed flame ignition in turbulent flow, Combust. Sci. Technol. 186 (2014) 1552-1561.
[40] N. Saito, Y. Minamoto, B. Yenerdag, M. Shimura, M. Tanahashi, Effects of turbulence on ignition of methane–air and n-heptane–air fully premixed mixtures, Combust. Sci. Technol. 190 (2017) 452-470.
[41] C. Turquand d’Auzay, V. Papapostolou, S.F. Ahmed, N. Chakraborty, On the minimum ignition energy and its transition in the localised forced ignition of turbulent homogeneous mixtures, Combust. Flame 201 (2019) 104-117.
[42] F.A. Williams, Combustion theory: The fundamental theory of chemically reacting flow systems, 2nd ed., Westview Press, Benjamin Cummings, California, 1994.
[43] I. Glassman, R.A. Yetter, N.G. Glumac, Ignition, in: Combustion, Academic Press, Boston, 2015, pp. 363-391.
[44] C.K. Law, Combustion Physics, in, Cambridge University Press, New York, 2006.
[45] D.R. Ballal, A.H. Lefebvre, Ignition and flame quenching of flowing heterogeneous fuel-air mixtures, Combust. Flame 35 (1979) 155-168.
[46] M. Champion, B. Deshaies, G. Joulin, K. Kinoshita, Spherical flame initiation: Theory versus experiments for lean propane-air mixtures, Combust. Flame 65 (1986) 319-337.
[47] D.R. Ballal, A.H. Lefebvre, A general model of spark ignition for gaseous and liquid fuel-air mixtures, Symp. Int. Combust. 18 (1981) 1737-1746.
[48] P.S. Tromans, R.M. Furzeland, An analysis of Lewis number and flow effects on the ignition of premixed gases, Symp. Int. Combust. 21 (1988) 1891-1897.
[49] P. Boudier, S. Henriot, T. Poinsot, T. Baritaud, A model for turbulent flame ignition and propagation in spark ignition engines, Symp. Int. Combust. 24 (1992) 503-510.
[50] F. Wu, A. Saha, S. Chaudhuri, C.K. Law, Facilitated ignition in turbulence through differential diffusion, Phys. Rev. Lett. 113 (2014) 024503.
[51] A. Saha, S. Yang, C.K. Law, On the competing roles of turbulence and differential diffusion in facilitated ignition, Proc. Combust. Inst. 37 (2019) 2383-2390.
[52] S.S. Shy, M.T. Nguyen, S.-Y. Huang, C.-C. Liu, Is turbulent facilitated ignition through differential diffusion independent of spark gap?, Combust. Flame 185 (2017) 1-3.
[53] S.S. Shy, M.T. Nguyen, S.Y. Huang, Effects of electrode spark gap, differential diffusion, and turbulent dissipation on two distinct phenomena: Turbulent facilitated ignition versus minimum ignition energy transition, Combust. Flame 205 (2019) 371-377.
[54] C. Cardin, B. Renou, G. Cabot, A.M. Boukhalfa, Experimental analysis of laser-induced spark ignition of lean turbulent premixed flames: New insight into ignition transition, Combust. Flame 160 (2013) 1414-1427.
[55] C. Cardin, B. Renou, G. Cabot, A. Boukhalfa, Experimental analysis of laser-induced spark ignition of lean turbulent premixed flames, CR Mecanique 341 (2013) 191-200.
[56] X. Yu, S. Yu, Z. Yang, Q. Tan, et al., Improvement on energy efficiency of the spark ignition system, (2017).
[57] T. Alger, J. Gingrich, B. Mangold, C. Roberts, A continuous discharge ignition system for EGR limit extension in SI engines, SAE Int. J. Engines 4 (2011) 677-692.
[58] X. Yu, Z. Yang, S. Yu, X. huo, et al., Boosted current spark strategy for lean burn spark ignition engines, (2018).
[59] S.V. Pancheshnyi, D.A. Lacoste, A. Bourdon, C.O. Laux, Ignition of propane–air mixtures by a repetitively pulsed nanosecond discharge, IEEE Trans. Plasma Sci. 34 (2006) 2478-2487.
[60] A.A. Tropina, A.P. Kuzmenko, S.V. Marasov, D.V. Vilchinsky, Ignition system based on the nanosecond pulsed discharge, IEEE Trans. Plasma Sci. 42 (2014) 3881-3885.
[61] S. Lovascio, T. Ombrello, J. Hayashi, S. Stepanyan, et al., Effects of pulsation frequency and energy deposition on ignition using nanosecond repetitively pulsed discharges, Proc. Combust. Inst. 36 (2017) 4079-4086.
[62] D. Xu, Thermal and hydrodynamic effects of nanosecond discharges in air and application to plasma-assisted combustion, Ecole Centrale Paris, 2013. https://tel.archives-ouvertes.fr/tel-00978527.
[63] M. Castela, S. Stepanyan, B. Fiorina, A. Coussement, et al., A 3-D DNS and experimental study of the effect of the recirculating flow pattern inside a reactive kernel produced by nanosecond plasma discharges in a methane-air mixture, Proc. Combust. Inst. 36 (2017) 4095-4103.
[64] S. Lovascio, J. Hayashi, S. Stepanyan, G.D. Stancu, C.O. Laux, Cumulative effect of successive nanosecond repetitively pulsed discharges on the ignition of lean mixtures, Proc. Combust. Inst. 37 (2019) 5553-5560.
[65] D.A. Xu, D.A. Lacoste, C.O. Laux, Ignition of Quiescent Lean Propane–Air Mixtures at High Pressure by Nanosecond Repetitively Pulsed Discharges, Plasma Chem. Plasma P. 36 (2015) 309-327.
[66] A.P. Kelley, G. Jomaas, C.K. Law, Critical radius for sustained propagation of spark-ignited spherical flames, Combust. Flame 156 (2009) 1006-1013.
[67] Z. Chen, M.P. Burke, Y. Ju, Effects of Lewis number and ignition energy on the determination of laminar flame speed using propagating spherical flames, Proc. Combust. Inst. 32 (2009) 1253-1260.
[68] D.A. Xu, M.N. Shneider, D.A. Lacoste, C.O. Laux, Thermal and hydrodynamic effects of nanosecond discharges in atmospheric pressure air, J. Phys. D: Appl. Phys. 47 (2014).
[69] J.K. Lefkowitz, P. Guo, T. Ombrello, S.H. Won, et al., Schlieren imaging and pulsed detonation engine testing of ignition by a nanosecond repetitively pulsed discharge, Combust. Flame 162 (2015) 2496-2507.
[70] J.K. Lefkowitz, T. Ombrello, An exploration of inter-pulse coupling in nanosecond pulsed high frequency discharge ignition, Combust. Flame 180 (2017) 136-147.
[71] R. Ono, M. Nifuku, S. Fujiwara, S. Horiguchi, T. Oda, Gas temperature of capacitance spark discharge in air, Journal of Applied Physics 97 (2005) 123307.
[72] R. Ono, M. Nifuku, S. Fujiwara, S. Horiguchi, T. Oda, Minimum ignition energy of hydrogen–air mixture: Effects of humidity and spark duration, J. Electrostat 65 (2007) 87-93.
[73] A. Kumamoto, H. Iseki, R. Ono, T. Oda, Measurement of minimum ignition energy in hydrogen-oxygen-nitrogen premixed gas by spark discharge, J. Phys. Conf. Ser 301 (2011) 012039.
[74] E. Randeberg, W. Olsen, R.K. Eckhoff, A new method for generation of synchronised capacitive sparks of low energy, J. Electrostat 64 (2006) 263-272.
[75] M. Thiele, J. Warnatz, A. Dreizler, S. Lindenmaier, et al., Spark ignited hydrogen/air mixtures: two dimensional detailed modeling and laser based diagnostics, Combust. Flame 128 (2002) 74-87.
[76] J.J. Lee, J.E. Shepherd, in, Graduate Aeronautical Laboratories, California Institute of Technology, 2000.
[77] J.D. Colwell, A. Reza, Hot surface ignition of automotive and aviation fluids, Fire Technology 41 (2005) 105-123.
[78] U. Maas, J. Warnatz, Ignition processes in hydrogen-oxygen mixtures, Combust. Flame 74 (1988) 53-69.
[79] A. Frendi, M. Sibulkin, Dependence of minimum ignition energy on ignition parameters, Combust. Sci. Technol. 73 (1990) 395-413.
[80] T. Sloane, P. Ronney, A comparison of ignition phenomena modelled with detailed and simplified kinetics, Combust. Sci. Technol. 88 (1993) 1-13.
[81] H.J. Kim, S.H. Chung, C.H. Sohn, Numerical calculation of minimum ignition energy for hydrogen and methane fuels, KSME International Journal 18 (2004) 838-846.
[82] I.B. Zeldovich, G.I. Barenblatt, V.B. Librovich, G.M. Makhviladze, Mathematical theory of combustion and explosions, Consultants Bureau,New York, NY, United States, 1985.
[83] B. Deshaies, G. Joulin, On the initiation of a spherical flame kernel, Combust. Sci. Technol. 37 (1984) 99-116.
[84] L. He, Critical conditions for spherical flame initiation in mixtures with high Lewis numbers, Combust. Theor. Model 4 (2000) 159-172.
[85] G. Joulin, T. Mitani, Linear stability analysis of two-reactant flames, Combust. Flame 40 (1981) 235-246.
[86] C.C. Liu, S.S. Shy, H.C. Chen, M.W. Peng, On interaction of centrally-ignited, outwardly-propagating premixed flames with fully-developed isotropic turbulence at elevated pressure, Proc. Combust. Inst. 33 (2011) 1293-1299.
[87] C. Liu, S.S. Shy, M. Peng, C. Chiu, Y. Dong, High-pressure burning velocities measurements for centrally-ignited premixed methane/air flames interacting with intense near-isotropic turbulence at constant Reynolds numbers, Combust. Flame 159 (2012) 2608-2619.
[88] L.J. Jiang, S.S. Shy, W.Y. Li, H.M. Huang, M.T. Nguyen, High-temperature, high-pressure burning velocities of expanding turbulent premixed flames and their comparison with Bunsen-type flames, Combust. Flame 172 (2016) 173-182.
[89] M.T. Nguyen, D.W. Yu, S.S. Shy, General correlations of high pressure turbulent burning velocities with the consideration of Lewis number effect, Proc. Combust. Inst. 37 (2019) 2391-2398.
[90] S.S. Shy, W.J. Lin, K.Z. Peng, High-intensity turbulent premixed combustion: General correlations of turbulent burning velocities in a new cruciform burner, Proc. Combust. Inst. 28 (2000) 561-568.
[91] S.S. Shy, W.J. Lin, J.C. Wei, An experimental correlation of turbulent burning velocities for premixed turbulent methane-air combustion, Proc. R. Soc. A 456 (2000) 1997-2019.
[92] T.S. Yang, S.S. Shy, Two-way interaction between solid particles and homogeneous air turbulence: particle settling rate and turbulence modification measurements, J. Fluid Mech. 526 (2005) 171-216.
[93] D.A. Xu, D.A. Lacoste, C.O. Laux, Ignition of quiescent lean propane–air mixtures at high pressure by nanosecond repetitively pulsed discharges, Plasma Chem. Plasma P. 36 (2016) 309-327.
[94] W. Liang, C.K. Law, Z. Chen, Ignition of hydrogen/air mixtures by a heated kernel: Role of Soret diffusion, Combust. Flame 197 (2018) 416-422.
[95] N. Chakraborty, R.S. Cant, Influence of Lewis number on curvature effects in turbulent premixed flame propagation in the thin reaction zones regime, Physics of Fluids 17 (2005).
[96] M.T. Nguyen, S.S. Shy, Y.R. Chen, B.L. Lin, S.Y. Huang, Conventional Spark versus Nanosecond Repetitively Pulsed Discharge for A Turbulent Facilitated Ignition Phenomenon, 38th Internal Symposium on Combustion (2020).
[97] N. Iida, Research and development of super-lean burn for high efficiency SI engine, The Proceedings of the International symposium on diagnostics and modeling of combustion in internal combustion engines 2017.9 (2017) Plenary Lecture (PL-1). |