Design and Mechanism of Laser Ignition in Internal Combustion Engines

Authors

  • Mohit Verma Guru Kashi University, Talwandi Sabo Author
  • Kewal Singh Guru Kashi University, Talwandi Sabo Author

DOI:

https://doi.org/10.61841/b28wav27

Abstract

 Significant Probable Because start starts burning as well as impacts following ignition, the exhibition of
future start frameworks for gas powered motors ought to be solid and effective to improve and safeguard
ignition dependability. Lean consume frameworks have been hailed as a state of the art ignition strategy
that can help warm effectiveness while bringing down contaminations. Current motors, then again, can't
run incline enough in view of start issues like lazy fire commencement and spread, as well as the chance
of fizzling. High fumes gas distribution motors have a comparable potential for discharges decrease,
however they may likewise have comparative touching off issues, particularly during standing by.
Likewise, start is a key plan thought in gas turbine and rocket combustor plans. Perhaps the most
encouraging start advances for gas powered motor in the near future is the laser spark plug. Laser ignition
has shown to be an effective igniting method for achieving higher engine efficiency while lowering
pollution. Pollution has been a serious concern in IC engines as a result of unburned fuel during the
ignition stage. To avoid intolerable pollutants, the endurance of laser spark plugs in ignition systems has
been increased, and it has prevailed theoretically and practically. One of the potential benefits of the laser
spark plug is that it can shift the location of combustion to where it is most needed. This paper is a review
of various ignition system research, including a study of the spatial light modulator (SPL), a brief
overview of spark plugs, performance of IC engines on single cylinder IC engines, and the use of laser
ignition to initiate combustion in an engine running on hydrogen–air mixtures. Study of an excimer laser
with an unstable resonator used as a laser source in laser ignition, comparison of engine performance with
a conventional and a laser spark plug, theoretical comparison of emissions features in conventional and
laser spark plugs. 

Downloads

Download data is not yet available.

References

1. G. Liedl, D. Schu¨ocker, B. Geringer, J. Graf, D. Klawatsch, H. Lenz, W. Piock, M.

Jetzinger, and P. Kapus, “Laser induced ignition of gasoline direct injection engines,” in

Proc. SPIE, 5777, pp. 955–960, 2004.Invited paper. 2. P. D. Ronney, “Laser versus

Conventional ignition of flames,” Optical Engineering 33 (2), pp. 510– 521, 1994.

2. Pankaj Hatwar1, DurgeshVerma, " Laser Ignition in Internal Combustion Engines”

International Journal of Modern Engineering Research (IJMER) www.ijmer.com Vol.2Issue.2, Mar-Apr 2012 pp-341- 345 ISSN: 2249-6645 www.ijmer.com 341

3. P. D. Ronney, “Laser versus conventional ignition of flames,” Optical Engineering 33 (2),

pp. 510– 521, 1994.

4. G. Liedl, D. Schu¨ockera, B. Geringer, J. Graf, D. Klawatsch, H.P. Lenz, W.F.

Piock, Jetzinger, P. Kapus D. R. Lidde, ed.,” Laser induced ignition of gasoline direct

Injection engines” CRC Handbook of Chemistry and Physics, CRC Press, 2000

5. M. Gower, “Krf laser-induced breakdown of gases,” Opt. Commun. 36, No. 1, pp. 43–45,

1981.

6. P. Ronney, “Laser versus conventional ignition of flames,” Opt. Eng. 33 (2), pp. 510–521,1994.

7. J. Syage, E. Fournier, R. Rianda, and R. Cohn, “Dynamics of flame propagation using laserInduced spark initiation: Ignition energy measurements,” Journal of Applied Physics 64 (3),

pp. 1499–1507, 1988.

8. T. Huges, Plasma and laser light, Adam Hilger, Bristol, 1975.

9. D. R. Lidde, ed., CRC Handbook of Chemistry and Physics, CRC Press, 2000.

10. Lambda Physik, Manual for the LPX205 Excimer Laser, 1991.

11. M. Lavid, A. Poulos, and S. Gulati, “Infrared multiphoton ignition and combustion

Enhancement of natural gas,” in SPIE Proc.: Laser Applications in Combustion and

Combustion Diagnostics, 1862, pp. 33–44, 1993.

12. M. Lavid, A. Poulos, and S. Gulati, “Infrared multiphoton ignition and combustion

Enhancement of natural gas,” in SPIE Proc.: Laser Applications in Combustion and

Combustion Diagnostics, 1862, pp. 33–44, 1993.

13. J. Ma, D. Alexander, and D. Poulain, “Laser spark ignition and combustion characteristics of

Methane-air mixtures,” Combustion and Flame 112 (4), pp. 492–506, 1998.

14. Bergmann and Schaefer, Lehrbuch der Experimentalphysik: Elektrizit¨at und Magnetisms,

vol. 2, Walter de Gruyter Berlin, 1981.

15. L. D. Landau and E. Lifschitz, Hydrodynamik, vol. 6 of Lehrbuch der theoretischenPhysik,

Harri Deutsch, Lehrbuch der theoretischenPhysik ed., 1991.

Downloads

Published

01.10.2024

How to Cite

Design and Mechanism of Laser Ignition in Internal Combustion Engines. (2024). International Journal of Psychosocial Rehabilitation, 25(2), 1466-1475. https://doi.org/10.61841/b28wav27