International Journal of Automotive Technology

  • 제7권5호
  • /
  • Pages.519-526
  • /
  • 2006
  • /
  • 1229-9138(pISSN)
  • /
  • 1976-3832(eISSN)
한국자동차공학회 (The Korean Society of Automotive Engineers)
권호 표지

EFFECT OF FUEL STRATIFICATION ON INITIAL FLAME DEVELOPMENT: PART 1-WITHOUT SWIRL

  • Ohm, I.Y. (Department of Mechanical Engineering and Graduate School of Energy & Environment, Seoul National University of Technology) ;
  • Park, C.J. (Department of Mechanical Engineering and Graduate School of Energy & Environment, Seoul National University of Technology)
  • 발행 : 2006.08.01
PDF 다운로드
⟨ 이전 논문 다음 논문 ⟩

초록

For investigating the effect of fuel stratification on flame propagation, initial flame development and propagation were visualized under different axially stratified states in a port injection SI engine. Stratification was controlled by the combination of the port swirl ratio and injection timing. Experiments were performed in an optical single cylinder engine modified from a production engine and images were captured through the quartz window mounted in the piston by an intensified CCD camera. Firstly in this paper, the characteristics under no port-generated swirl condition, i.e. normal conventional case was studied. Under various stratified conditions, flame images were captured at the pre-set crank angles. These were averaged and processed to characterize the flames propagation. The flame stability was estimated by the weighted average of flame area and luminosity. The stability was also evaluated through the standard deviation of flame area and propagation distance, and mean absolute deviation of propagating direction. Results show that stratification state according to injection timing do not affect on the direction of flame propagation. The flame development and the initial flame stability are strongly dependent on the stratified conditions and the initial flame stability is closely related to the engine stability and lean misfire limit.

키워드

참고문헌

  1. Ando, H., Akishino, K. (1991). Concept of lean combustion by barrel-stratification. SAE Paper No. 912207
  2. Heywood, J. B. (1988). Internal Combustion Engine Fundamentals. MacGraw-Hill. New York. 371-375
  3. Horie, K. (1992). The Development of high fuel economy and high performance four-valve lean burn engine. SAE Paper No. 920455
  4. Matsushita, S. (1985a). Development of the Toyota lean combustion system. SAE Paper No. 850044
  5. Matsusita, S. (1985b). Effects of helical port with swirl control valve on the combustion and performance of SI engine. SAE Paper No. 850046
  6. Ohm, I. Y., Ahn, H. S., Lee, W. J., Kim, W. T., Park, S. S. and Lee, D. U. (1994). Development of HMC axially stratified lean combustion engine. 1993 SAE Trans. 103, 3, 1298-1311
  7. Ohm, I. Y., Jeong, K. S. and Jeung, I. S. (1998). Effects of injection timing on the lean misfire limit in an SI engine. 1997 SAE Trans. 106, 3, 42-55
  8. Ohm, I. Y. and Cho, Y. S. (2001). In-cylinder fuel behavior according to fuel injection timing and port characteristics in an SI engine: Part I-Without swirl. Trans. Korean Society of Automotive Engineers 9, 2, 19-27
  9. Ohm, I. Y. and Park, C. J. (2002). Experimental study on axial stratification process and its effects (1), J. Mechanical Science and Technology 16, 11, 1457-1469
  10. Quader, A. A. (1982). The axially-stratified-charge engine. SAE Paper No. 820131
  11. Stone, R. (1992). Introduction to Internal Combustion Engines 2nd Edn.. MACMILLAN. London. 72-74
  12. Takeda, K. (1985). Toyota central injection (CI) system for lean combustion and high transient response. SAE Paper No. 851675