Advanced search
Publication Cover
Combustion Theory and Modelling Volume 26, 2022 - Issue 1
Submit an article Journal homepage
359
Views
3
CrossRef citations to date
0
Altmetric
Articles

Hotspot auto-ignition induced detonation development: emphasis on energy density and chemical reactivity

Jiaying Pana State Key Laboratory of Engines, Tianjin University, Tianjin, People’s Republic of ChinaView further author information
,
Lei Wanga State Key Laboratory of Engines, Tianjin University, Tianjin, People’s Republic of ChinaView further author information
,
Yu Hea State Key Laboratory of Engines, Tianjin University, Tianjin, People’s Republic of ChinaView further author information
,
Haiqiao Weia State Key Laboratory of Engines, Tianjin University, Tianjin, People’s Republic of ChinaCorrespondence[email protected]
View further author information
,
Gequn Shua State Key Laboratory of Engines, Tianjin University, Tianjin, People’s Republic of ChinaView further author information
&
Tao Lib Guangzhou Institute of Energy Conversion, Chinese Academy of Sciences, Guangzhou, People’s Republic of ChinaView further author information
Pages 179-200 | Received 12 Jul 2021, Accepted 11 Oct 2021, Published online: 13 Nov 2021

References

  • Z. Wang, H. Liu and R.D. Reitz, Knocking combustion in spark-ignition engines. Prog. Energy Combust. Sci 61 (2017), pp. 78–112.
  • M. Liberman, M. Ivanov, O. Peil, D. Valiev and L.-E. Eriksson, Numerical modeling of the propagating flame and knock occurrence in spark-ignition engines. Combust. Sci. Technol 177 (2004), pp. 151–182.
  • J. Pan, G. Shu and H. Wei, Interaction of flame propagation and pressure waves during knocking combustion in spark-ignition engines. Combust. Sci. Technol 186 (2014), pp. 192–209.
  • C. Dahnz and U. Spicher, Irregular combustion in supercharged spark ignition engines–pre-ignition and other phenomena. Int. J. Eng. Res 11 (2010), pp. 485–498.
  • N. Peters, B. Kerschgens and G. Paczko, Super-knock prediction using a refined theory of turbulence. SAE Int. J. Engines 6 (2013), pp. 953–967.
  • M.D. Kurtz and J.D. Regele, Acoustic timescale characterisation of a one-dimensional model hot spot. Combust. Theory Model 18 (2014), pp. 532–551.
  • Z. Wang, Y. Qi, X. He, J. Wang, S. Shuai and C.K. Law, Analysis of pre-ignition to super-knock: hotspot-induced deflagration to detonation. Fuel 144 (2015), pp. 222–227.
  • A. Robert, S. Richard, O. Colin and T. Poinsot, LES study of deflagration to detonation mechanisms in a downsized spark ignition engine. Combust Flame 162 (2015), pp. 2788–2807.
  • H. Wei, X. Zhang, H. Zeng, R. Deiterding, J. Pan and L. Zhou, Mechanism of end-gas autoignition induced by flame-pressure interactions in confined space. Phys Fluids 31 (2019), pp. 076106.
  • A. Kapila, D. Schwendeman, J. Quirk and T. Hawa, Mechanisms of detonation formation due to a temperature gradient. Combust. Theory Model 6 (2002), pp. 553.
  • J. Meyer and A. Oppenheim, On the shock-induced ignition of explosive gases. Symp. (Int.) Combust 13 (1971), pp. 1153–1164.
  • Y.B. Zeldovich, Regime classification of an exothermic reaction with nonuniform initial conditions. Combust Flame 39 (1980), pp. 211–214.
  • A. Bartenev and B. Gelfand, Spontaneous initiation of detonations. Prog. Energy Combust. Sci 26 (2000), pp. 29–55.
  • S.L. Kokjohn, R.M. Hanson, D. Splitter and R. Reitz, Fuel reactivity controlled compression ignition (RCCI): a pathway to controlled high-efficiency clean combustion. Int. J. Eng. Res 12 (2011), pp. 209–226.
  • A.M. Khokhlov, E.S. Oran and J.C. Wheeler, A theory of deflagration-to-detonation transition in unconfined flames. Combust Flame 108 (1997), pp. 503–517.
  • D.R. Kassoy, J.A. Kuehn, M. Nabity and J. Clarke, Detonation initiation on the microsecond time scale: DDTs. Combust. Theory Model 12 (2008), pp. 1009–1047.
  • A. Guerouani, A. Robert and J.-M. Zaccardi, Detonation peninsula for TRF-air mixtures: assessment for the analysis of auto-ignition events in spark-ignition engines, 0148-7191, SAE Technical Paper, 2018.
  • G. Goyal, U. Maas and J. Warnatz, Simulation of the Transition from Deflagration to Detonation, SAE transactions (1990), pp. 1-10.
  • G. Goyal, J. Warnatz and U. Maas, Numerical studies of hot spot ignition in H2− O2 and CH4-air mixtures. Symp. (Int.) Combust 23 (1991), pp. 1767–1773.
  • H.-J. Weber, A. Mack and P. Roth, Combustion and pressure wave interaction in enclosed mixtures initiated by temperature nonuniformities. Combust Flame 97 (1994), pp. 281–295.
  • A.E. Lutz, R.J. Kee, J.A. Miller, H.A. Dwyer and A.K. Oppenheim, Dynamic effects of autoignition centers for hydrogen and C1, 2-hydrocarbon fuels. Symp. (Int.) Combust 22 (1989), pp. 1683–1693.
  • X. Gu, D. Emerson and D. Bradley, Modes of reaction front propagation from hot spots. Combust Flame 133 (2003), pp. 63–74.
  • D. Bradley, Autoignitions and detonations in engines and ducts. Philos. Trans. R. Soc. London, Ser A 370 (2012), pp. 689–714.
  • L. Bates and D. Bradley, Deflagrative, auto-ignitive, and detonative propagation regimes in engines. Combust Flame 175 (2017), pp. 118–122.
  • P. Dai, Z. Chen, S. Chen and Y. Ju, Numerical experiments on reaction front propagation in n-heptane/air mixture with temperature gradient. Proc. Combust. Inst 35 (2015), pp. 3045–3052.
  • P. Dai, C. Qi and Z. Chen, Effects of initial temperature on autoignition and detonation development in dimethyl ether/air mixtures with temperature gradient. Proc. Combust. Inst 36 (2017), pp. 3643–3650.
  • J. Rudloff, J.-M. Zaccardi, S. Richard and J. Anderlohr, Analysis of pre-ignition in highly charged SI engines: Emphasis on the auto-ignition mode. Proc. Combust. Inst 34 (2013), pp. 2959–2967.
  • C. Qi, P. Dai, H. Yu and Z. Chen, Different modes of reaction front propagation in n-heptane/air mixture with concentration non-uniformity. Proc. Combust. Inst 36 (2017), pp. 3633–3641.
  • M.B. Luong, T. Lu, S.H. Chung and C.S. Yoo, Direct numerical simulations of the ignition of a lean biodiesel/air mixture with temperature and composition inhomogeneities at high pressure and intermediate temperature. Combust Flame 161 (2014), pp. 2878–2889.
  • M.B. Luong, F.E.H. Pérez and H.G. Im, Prediction of ignition modes of NTC-fuel/air mixtures with temperature and concentration fluctuations. Combust Flame 213 (2020), pp. 382–393.
  • H.A. El-Asrag and Y. Ju, Direct numerical simulations of exhaust gas recirculation effect on multistage autoignition in the negative temperature combustion regime for stratified HCCI flow conditions by using H2O2 addition. Combust. Theory Model 17 (2013), pp. 316–334.
  • T. Zhang, W. Sun and Y. Ju, Multi-scale modeling of detonation formation with concentration and temperature gradients in n-heptane/air mixtures. Proc. Combust. Inst 36 (2017), pp. 1539–1547.
  • P. Dai, Z. Chen, X. Gan and M.A. Liberman, Autoignition and detonation development from a hot spot inside a closed chamber: Effects of end wall reflection. Proc. Combust. Inst 38 (2020), pp. 5905–5913.
  • M.B. Luong, S. Desai, F.E.H. Pérez, R. Sankaran, B. Johansson and H.G. Im, A statistical analysis of developing knock intensity in a mixture with temperature inhomogeneities. Proc. Combust. Inst 38 (2021), pp. 5781–5789.
  • Y. Zhuang, Q. Li, P. Dai and H. Zhang, Autoignition and detonation characteristics of n-heptane/air mixture with water droplets. Fuel 266 (2020), pp. 117077.
  • Z. Yu, H. Zhang and P. Dai, Autoignition and detonation development induced by temperature gradient in n-C7H16/air/H2O mixtures. Phys Fluids 33 (2021), pp. 017111.
  • C.A. Towery, A.Y. Poludnenko and P.E. Hamlington, Detonation initiation by compressible turbulence thermodynamic fluctuations. Combust Flame 213 (2020), pp. 172–183.
  • J. Pan, S. Dong, T. Li, Y. He, H. Wei and J. Jiang, Numerical simulations on autoignition propagation modes under reciprocating engine-relevant conditions. Combust. Sci. Technol 193 (2020), pp. 2241–2258.
  • J. Pan, S. Dong, H. Wei, T. Li, G. Shu and L. Zhou, Temperature gradient induced detonation development inside and outside a hotspot for different fuels. Combust Flame 205 (2019), pp. 269–277.
  • Y. Qi, Z. Wang, J. Wang and X. He, Effects of thermodynamic conditions on the end gas combustion mode associated with engine knock. Combust Flame 162 (2015), pp. 4119–4128.
  • J. Pan, Z. Hu, Z. Pan, G. Shu, H. Wei, T. Li and C. Liu, Auto-ignition and knocking characteristics of gasoline/ethanol blends in confined space with turbulence. Fuel 294 (2021), pp. 120559.
  • D. Bradley and G.T. Kalghatgi, Influence of autoignition delay time characteristics of different fuels on pressure waves and knock in reciprocating engines. Combust Flame 156 (2009), pp. 2307–2318.
  • H. Yu and Z. Chen, End-gas autoignition and detonation development in a closed chamber. Combust Flame 162 (2015), pp. 4102–4111.
  • J. Su, P. Dai and Z. Chen, Detonation development from a hot spot in methane/air mixtures: Effects of kinetic models. Int. J. Eng. Res 22 (2020), pp. 2597–2606.
  • H. Wei, Z. Hu, J. Pan, X. Wang, L. Zhou and F. Liu, Effect of fuel properties on knocking combustion in an optical rapid compression machine. Energy Fuels 33 (2019), pp. 12714–12722.
  • Y. Gao, P. Dai and Z. Chen, Numerical studies on autoignition and detonation development from a hot spot in hydrogen/air mixtures. Combust. Theory Model 24 (2020), pp. 245–261.
  • J. Pan, L. Chen, H. Wei, D. Feng, S. Deng and G. Shu, On autoignition mode under variable thermodynamic state of internal combustion engines. Int. J. Eng. Res 21 (2020), pp. 856–865.
  • R. Kee, F. Rupley and J. Miller, CHEMKIN-II: A FORTRAN chemical kinetics package for the analysis of gas phase chemical kinetics, Sandia Report SAND89-8009B, Sandia National Laboratories, Livermore, CA, USA, 1989.
  • R. Kee, J. Grcar, M. Smooke and J. Miller, PREMIX: A FORTRAN program for modeling steady laminar one-dimensional, Sandia Report SAND85-8240, Sandia National Laboratories, Livermore, CA, USA, 1985.
  • Z. Chen, M.P. Burke and 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), pp. 1253–1260.
  • Z. Chen, Effects of radiation and compression on propagating spherical flames of methane/air mixtures near the lean flammability limit. Combust Flame 157 (2010), pp. 2267–2276.
  • M. Sun and K. Takayama, Conservative smoothing on an adaptive quadrilateral grid. J. Comput. Phys 150 (1999), pp. 143–180.
  • R.F. Pachler, A.K. Ramalingam, K.A. Heufer and F. Winter, Reduction and validation of a chemical kinetic mechanism including necessity analysis and investigation of CH4/C3H8 oxidation at pressures up to 120 bar using a rapid compression machine. Fuel 172 (2016), pp. 139–145.
  • W.K. Metcalfe, S.M. Burke, S.S. Ahmed and H.J. Curran, A hierarchical and comparative kinetic modeling study of C1− C2 hydrocarbon and oxygenated fuels. Int. J. Chem. Kinet 45 (2013), pp. 638–675.
  • L. Bates, D. Bradley, G. Paczko and N. Peters, Engine hot spots: modes of auto-ignition and reaction propagation. Combust Flame 166 (2016), pp. 80–85.
  • J. Pan, Z. Hu, H. Wei, M. Pan, X. Liang, G. Shu and L. Zhou, Understanding strong knocking mechanism through high-strength optical rapid compression machines. Combust Flame 202 (2019), pp. 1–15.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.