CFD Investigation of the Effects of Re-Entrant Combustion Chamber Geometry in a HSDI Diesel Engine
Authors: Raouf Mobasheri, Zhijun Peng
Abstract:
A CFD simulation has applied to explore the effects of combustion chamber geometry on engine performance and pollutant emissions in a HSDI diesel engine. Three ITs (Injection Timing) at 2.65 CA BTDC, 0.65 CA BTDC and 1.35 CA ATDC, all with 30 crank angle pilot separations has firstly considered to identify the optimum IT for achieving the minimum amount of pollutant emissions. In order to investigate the effect of combustion chamber, thirteen different piston bowl configurations have been designed and analyzed. For all the studied cases, compression ratio, squish bowl volume and the amount of injected fuel were kept constant to assure that variation in the engine performance were only caused by geometric parameters. The results showed that by changing the geometric parameters on piston bowl, the amount of emission pollutants can be decreased while the other performance parameters of engine remain constant.
Keywords: HSDI Diesel Engine, Combustion Chamber Geometry, Pilot Injection, Injection Timing.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1336452
Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 4136References:
[1] Cowland, C., Gutmann, P., and Herzog, P. L., "Passenger vehicle diesel engines for the U.S.”, SAE Paper 2004-01-1452, 2004.
[2] Pischinger, F. F. The diesel engine for cars – is there a future? Trans. ASME, J. Engng Gas Turbines Power, 1998, 120(3), 641–647.
[3] Ge, H-W., Shi, Y., Reitz, R.D., and Willems, W., "Optimization of a high-speed direct-injection diesel engine at low-load operation using computational fluid dynamics with detailed chemistry and a multi-objective genetic algorithm”, Proc. IMechE, Part D:J. Automobile Engineering, 2010, 224(4): 547-563.
[4] Saito, T., Yasuhiro, D., Uchida, N., Ikeya, N., "Effects of Combustion Chamber Geometry on Diesel Combustion”, SAE Paper 861186, 1986.
[5] Bianchi, G.M., Pelloni, P., Corcione, F.E., Mattarelli, E., Luppino Bertoni, F., "Numerical Study of the Combustion Chamber Shape for Common Rail H.S.D.I. Diesel Engines”, SAE Paper 2000-01-1179, 2000.
[6] De Risi, A., Donateo, T., Laforgia, D., "Optimization of the combustion of direct injection diesel engines”, SAE Paper 2003-01-1064, 2003.
[7] Zhu, Y., Zhao, H., Melas, D. A., and Ladommatos, N., "Computational study of the effects of the re-entrant lip shape and toroidal radii of piston bowl on a HSDI diesel engine’s performance and emissions”, SAE Paper 2004-01-0118, 2004.
[8] Genzale, L. C. and Reitz, D. R., "Effects of Piston Bowl Geometry on Mixture Development and Late-Injection Low-Temperature Combustion in a Heavy-Duty Diesel Engine”, SAE Paper 2008-01-1330, 2008.
[9] Wickman, D.D., Yun, H. and Reitz, D., "Split-Spray Piston Geometry Optimization for HSDI Diesel Engine Combustion”, SAE Paper 2003-01-0348, 2003.
[10] Heywood, J. B., Internal Combustion Engine Fundamentals- Mc Graw-Hill New York, 1988.
[11] Zhang, L., "A study of pilot injection in a DI diesel engine”, SAE Paper 1999-01-3493, 1999.
[12] Chen, SK., "Simultaneous reduction of NOx and particulate emissions by using multiple injections in a small diesel engine”, SAE Paper 2000-01-3084, 2000.
[13] Tanaka, T., Ando, A., Ishizaka, K., "Study on pilot injection of DI diesel engine using common rail injection system”, JSAE Rev 2002; 23:297–302.
[14] ICE Physics & Chemistry, AVL FIRE user Manual v.2009.2, 2009.
[15] R. Tatschl, P. Priesching, J. Ruetz, "Recent Advances in DI-Diesel Combustion Modeling in AVL FIRE - A Validation Study”, International Multidimensional Engine Modeling User’s Group Meeting at the SAE Congress, Detroit, 2007.
[16] R. Mobasheri, Zhijun Peng and S. M. Mirsalim, "CFD Evaluation of Effects of Split Injection on Combustion and Emissions in a DI Diesel Engine”, SAE 2011 World Congress, April 12-14, 2011, Cobo Center, Detroit, Michigan, USA, SAE Paper number: 2011-01-0822.
[17] Hélie, J. &Trouvé, A., "A modified coherent flame model to describe turbulent flame propagation in mixtures with variable composition”, Proc. Combust. Inst. 28, (2000): 193-201.
[18] Colin, O., Benkenida, A., "The 3-Zones Extended Coherent Flame Model (ECFM3Z) for Computing Premixed / Diffusion Combustion”, Oil & Gas Science and Technology – Rev. IFP, Vol. 59, No. 6, 2004, pp. 593-609.
[19] Halstead, M., Kirsch, L. and Quinn, C., "The Auto Ignition of Hydrocarbon Fueled at High Temperatures and Pressures-Fitting of a Mathematical Model”, Combustion Flame, Vol. 30, 45-60, 1977.
[20] Reitz, R. D. "Modeling Atomization Processes in High-Pressure Vaporizing Sprays”, Atomization and Spray Technology, Vol. 3: 309-337, 1987.
[21] Naber, J.D. and Reitz, R.D., "Modeling Engine Spray/Wall Impingement”, SAE Paper 880107, 1988.
[22] Corcione, F. E, Allocca, L., Pelloni, P., Bianchi, G. M., and Luppino, F., ”Modeling atomization and drop breakup of high-pressure Diesel Sprays”, ASME Journal of Engineering for Gas Turbine and Power, Vol. 123, Issue 2, pp. 419-427, 2001.
[23] Dukowicz, J.K., "Quasi-Steady Droplet Change in the Presence Of Convection”, Informal Report Los Alamos Scientific Laboratory, LA7997-MS.
[24] Han, Z. and Reitz, R. D., "Turbulence modelling of internal combustion engines using RNG k–e models”, Combust. Sci. and Technol., 1995, 106, 267–295.
[25] Hioyasu, H., and Nishida, K. "Simplified Three Dimensional Modeling of Mixture Formation and Combustion in a DI Diesel Engine”, SAE Paper 890269, 1989.
[26] Zhu, Y., Zhao, H.,Melas, D. A., and Ladommatos, N., "Computational study of the effects of the geometry of piston bowl pip for a high-speed direct-injection diesel engine”, Proc. IMechE, Part D: J. Automobile Engineering, 2004, 218, 875–890.