Transactions of the Korean Society of Automotive Engineers (한국자동차공학회논문집)

The Korean Society of Automotive Engineers (한국자동차공학회)
권호 표지

Effects of the EGR and Injection Pressure on the Combustion and Emission Characteristics of DME Commonrail Diesel Engine

DME를 연료로 하는 커먼레일 디젤 엔진의 연소와 배기 특성에 미치는 분사압력과 EGR의 영향

  • 정재우 (자동차부품연구원 첨단동력/IT 종합연구센터) ;
  • 강정호 (자동차부품연구원 첨단동력/IT 종합연구센터) ;
  • 이성만 (자동차부품연구원 첨단동력/IT 종합연구센터) ;
  • 김현철 (자동차부품연구원 첨단동력/IT 종합연구센터) ;
  • 강우 (자동차부품연구원 첨단동력/IT 종합연구센터)
  • Published : 2006.07.01
Download PDF
⟨ Previous Next ⟩

Abstract

In this study, the effect of EGR and fuel injection pressure on the characteristics of combustion and emission performance of the common-rail diesel engine is investigated using DME fuel as a smoke-free alternative fuel. Because the heating value and density of DME fuel are lower than those of diesel fuel, the injection duration of the DME engine is relatively longer than the injection duration of the diesel engine with the same injection pressure. However, the higher injection pressure can shorten the injection duration for the DME engine. Although the smoke level of the DME engine is much lower than that of the diesel engine, the NOx is at a level similar to that of the diesel engine. As a proposed solution for this, the EGR technique is empirically applied to the DME engine. In the experiments, the injection pressure was changed from 200bar to 400bar, and the EGR rate was limited under 40%. With the same injection timing and fuel amount, the experiment results indicated that the increase of injection pressure led to the increase of IMEP while decreasing HC and CO emissions. However, the NOx emission tends to increase as the injection pressure becomes higher. On the other hand, as the EGR rate was increased, NOx emission and A/F were reduced while the HC and CO emissions were increased. Because HC and CO emissions have the critical A/F point where the emissions of HC and CO are rapidly increased, it is proposed that the EGR rate must be limited under the critical EGR rate.

Keywords

References

  1. K. W. Jun and H. S. Roh, 'DME Manufactoring Technology: State of the Art,' Journal of KSAE, Vol.25, No.4, pp.13-16, 2003
  2. J. K. Oh, 'Prospect of DME Production Technology and Utilization,' Journal of KSAE, Vol.25, No.4, pp.17-26, 2003
  3. Y. J. Lee and Y. K. Kim, 'Status of Worldwide DME Engine Vehicle R & D,' Journal of KSAE, Vol.25, No.4, pp.27-32, 2003
  4. S.-H. Nam, Y.-J. Lee and Y.-K. Kim, 'Effects of EGR Rate on Exhaust Emission Characteristics of DI DME engine,' Spring Conference Proceedings, Vol.I, KSAE, pp.435-440, 2002
  5. J. S. Hwang, J. S. Ha and S. Y. No, 'Spray Characteristics of DME in Conditions of Common rail Injection System(II),' Int. J. Automotive Technology, Vol.4, No.3, pp.119-124, 2003
  6. W. Choi, J. K. Lee and C. S. Bae, 'Combustion Characteristics of Dimethyl Ether(DME) and Diesel Fuel Using a Common-rail Fuel Injection System,' Transactions of KSAE, Vol.12, No.6, pp.30-37, 2004
  7. S. Kajitani, Z. L. Chen, M. Konno and K. T. Rhee, 'Engine Performance and Exhaust Characteristics of Direct-injection Diesel Engine Operated with DME,' SAE 972973, 1997
  8. P. Kapus and H. Ofner, 'Development of Fuel injection Equipment and Combustion System for DI Diesel Operated on Dimethyl Ether,' SAE 950062, 1995
  9. T. Ikeda, Y. Ohmori, A. Takamura, Y. Sato, L. Jun and T. Kamimoto, 'Measurement of the Rate of Multiple Fuel Injection with Diesel Fuel and DME,' SAE 2001-01-0527, 2001
  10. H. C. Kim, W. Kang, B. C. Na, J. W. Chung and M. H. Kim, 'Simulation of DME Engine for Exhaust Gas Prediction,' Fall Conference Proceedings, Vol.I, KSAE, pp.734-751, 2005
  11. S. H. Cho, B. M. Seong, D. Y. Lee and B. H. Lee, 'A Study on Measurements and Evaluation of Chemical Durability for DME,' Fall Conference Proceedings, Vol.I, KSAE, pp.342-347, 2003
  12. W. M. Silvis, 'An Algorithm for Calculating the Air/Fuel Ratio from Exhaust Emissions,' SAE 970514, 1997