TECHNICAL PAPERS: Internal Combustion Engines

Analysis of the Combustion Process in a EURO III Heavy-Duty Direct Injection Diesel Engine

[+] Author and Article Information
J. M. Desantes, J. V. Pastor, J. Arrègle, S. A. Molina

CMT–Departamento de Máquinas y Motores Térmicos, Universidad Politécnica de Valencia, Aptdo. 22012, 46071 Valencia Spaine-mail: cmt@mot.upv.es

J. Eng. Gas Turbines Power 124(3), 636-644 (Jun 19, 2002) (9 pages) doi:10.1115/1.1456460 History: Received July 01, 1999; Revised November 01, 2001; Online June 19, 2002
Copyright © 2002 by ASME
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Herzog, P. L., Buerguer, L., Winklhofer, E., Zelenka, P., and Cartellieri, W., 1992, “NOx Reduction Strategies for D.I. Diesel Engines,” SAE Paper 920470.
Knecht, W., Amann, G., and Gonzàlez-Balmas, F., 1992, “Truck Diesel Engine Development for Future Emission and Noise Standards,” Proceedings of the International Congress “The Powertrain: Development and Future,” Société des Ingenieurs de l’Automobile, pp. 290–298.
Havenith, C., Needham, J. R., Nicol, A. J., and Such, C. H., 1993, “Low Emission Heavy Duty Diesel Engine for Europe,” SAE Paper 932959.
Payri, F., Desantes, J. M., Leiva, A., and Armas, O., 1997, “Thermodynamic Model for the Experimental Diagnostics of the Combustion Process in D.I. Diesel Engines,” Proc. III Congreso Iberoamericano de Ingenierı́a Mecánica, La Habana, Cuba, Instituto Superior Politécnico José Antonio Echeverria (in Spanish).
Lapuerta,  M., Armas,  O., and Hernandez,  J. J., 1999, “Diagnostic of D.I. Diesel Combustion From In-Cylinder Pressure Signal by Estimation of Mean Thermodynamic Properties of the Gas,” Appl. Therm. Eng., 19, pp. 513–529.
Ishida,  M., Ueki,  H., Matsumura,  N., Yamaguchi,  M., and Luo,  G. F., 1996, “Diesel Combustion Analysis Based on Two Zone Model (Comparison Between Model Analysis and Experiment),” JSME Int. Journal, Series B, 39, No. 1, pp. 185–192.
Christian,  R., Knopf,  F., Jasmek,  A., and Schindler,  W., 1993, “A New Method for the Filter Smoke Number Measurement With Improved Sensitivity, (in German),” Motortechnische Zeitschrift, 54, pp. 16–22.
Pastor,  J. V., Arrègle,  J., and Palomares,  A., 2001, “Diesel Spray Image Segmentation With a Likelihood Ratio Test,” Appl. Opt., 40, No. 17, pp. 2876–2885.
Chmela, F., 1996, “Test Cycle Development EURO III for Heavy Duty Diesel Engines,” FISITA Congress, Prag.
Hiroyasu, H., and Arai, M., 1990, “Structures of Fuel Sprays in Diesel Engines,” SAE Paper 900475.
Feola, M., Pelloni, P., Cantone, G., Bella, G., Casoli, G., and Toderi, G., 1992, “Optimization of Injection Law for a D.I. Diesel Engine,” ASME Paper 92-ICE-4.
Khan,  I. M., 1970, “Formation and Combustion of Carbon in a Diesel Engine,” IME Symposium, 184, Part 3J.
Khan, I. M., Greeves, G., and Wang, C. H. T., 1973, “Factors Affecting Smoke and Gaseous Emissions From Direct Injection Diesel Engines and a Method of Calculation,” SAE Paper 730169.
Ahmad, T., and Plee, S. L., 1983, “Application of Flame Temperature Correlations to Emissions From a Direct-Injection Diesel Engine,” SAE Paper 831734.
Yu, R. C., and Shaded, S. M., 1981, “Effects of Injection Timing and Exhaust Gas Recirculation on Emissions From a D.I. Diesel Engine,” SAE Paper 811234.
Iida, N., and Watanabe, J., 1990, “Surrounding Gas Condition Effects on NOx and Particulates,” Proc. International Symposium COMODIA 90, Japan Society of Mechanical Engineers, Tokyo, pp. 625–632.
Desantes,  J. M., Lapuerta,  M., and Salavert,  J. M., 1996, “Study on Independant Effects of Diesel Engine Operating Conditions on Nitric Oxide Formation and Emissions Through Schematical Combustion Simulation,” Proc. Inst. Mech. Eng., 210, pp. 71–80.
Matsuoka, S., Kamimoto, T., and Kobayashi, H., 1984, “Photographic and Image Analysis Studies of Diesel Spray and Flame With a Rapid Compression Machine and a D.I. Diesel Engine (Interpretation and conceptual image),” SAE Paper 845009.
Balles, E. N., and Heywood, J. B., 1989, “Spray and Flame Structure in Diesel Combustion,” Basic Processes in Internal Combustion Engines, ICE-Vol. 6 , ASME, New York, pp. 1–7.
Gartner, U., Oberacker, H., and König, G., 1998, “Combustion Analysis of Modern HD Diesel Engines Using Pressure Indication and Film Technique,” 3 Internationales Indiziersymposium AVL Germany.
Arcoumanis, C., Hadjiapostolou, A., and Whitelaw, J. H., 1991, “Flow and Combustion in a Hydra Direct-Injection Diesel Engine,” SAE Paper 910177.
Werlberger, P., and Cartellieri, W. P., 1987, “Fuel Injection and Combustion Phenomena in a High Speed Diesel Engine Observed by Means of Endoscopic High Speed Photography,” SAE Paper 870097
Payri,  F., Pastor,  J. V., and Arrègle,  J., 1996, “Endoscopic High Speed Visualisation of Injection and Combustion Processes in a D.I. Diesel Engine,” Entropie, 200, pp. 7–15.
Espey,  C., and Dec,  J. E., 1995, “The Effect of TDC Temperature and Density on the Liquid-Phase Fuel Penetration in a D.I. Diesel Engine,” Transactions of the SAE,104, Section 4, pp. 1400–1414.
Correas, D., 1998, “Experimental and Theoretical Study of a Diesel Type Free Spray,” PhD thesis, Universidad Politécnica de Valencia, Spain (in Spanish).
Pastor, J. V., Encabo, E., and Ruiz, S., 2000, “New Modelling Approach for Fast Online Calculations in Sprays,” SAE Paper 2000-01-0287.
Wolfer, H. H., 1938, “Ignition Lag in Diesel Engines,” VDI-Forschungsheft 392 (translated by Royal Aircraft Establishment, Farnborough Library, No. 358, UDC 621-436.047, Aug. 1959).
Stringer,  F. W., Clarke,  A. E., and Clarke,  J. S., 1969–1970, “The Spontaneous Ignition of Hydrocarbon Fuels in a Flowing System,” Proc. Inst. Mech. Eng., 184, Part 3J.
Hiroyasu, H., Kadota, T., and Arai, M., 1980, “Supplementary Comments: Fuel Spray Characterization in Diesel Engines,” Combustion Modeling in Reciprocating Engines, J. N. Mattavi and C. A. Amann, eds., Plenum Press, New York, pp. 369–408.
Pischinger,  F., Reuter,  U., and Scheid,  E., 1988, “Self Ignition of Diesel Sprays and Its Dependence on Fuel Properties and Injection Parameters,” ASME J. Eng. Gas Turbines Power, 110, pp. 399–404.
Naber, J. D., and Siebers, D. L., 1996, “Effects of Gas Density and Vaporization on Penetration and Dispersion of Diesel Sprays,” SAE Paper 960034.
Siebers, D. L., 1998, “Liquid-Phase Fuel Penetration in Diesel Sprays,” SAE Paper 980809.
Verhoeven, D., Vanhemelryck, J. L., and Baritaud, T., 1998, “Macroscopic and Ignition Characteristics of High-Pressure Sprays of Single-Component Fuels,” SAE Paper 981069.
Ricou,  F. P., and Spalding,  D. B., 1961, “Measurements of Entrainment by Axisymmetrical Turbulent Jets,” J. Fluid Mech., 11, pp. 21–32.
Wakuri,  Y., Fujii,  M., Amitani,  T., and Tsuneya,  R., 1960, “Studies on the Penetration of Fuel Spray in a Diesel Engine,” Bull. JSME, 3, No. 9.
Chikahisha, T., and Murayama, T., 1995, “Theory and Experiments on Air-Entrainment in Fuel Sprays and Their Application to Interpret Diesel Combustion Processes,” SAE Paper 950447.
Kamimoto,  T., and Kobayashi,  H., 1991, “Combustion Processes in Diesel Engines,” Prog. Energy Combust. Sci., 17, pp. 163–189.


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HRL analysis for 2H and 8H arrangements. A-100.
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NOx relationship between 2H and 8H cases
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Soot comparison between 2H and 8H cases
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NOx—Smoke tradeoff. Mode A-100.
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NOx—Smoke tradeoff. Mode B-75.
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NOx—Smoke tradeoff. Mode C-100.
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INOx emissions versus maximum burnt gas temperature
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Spray tip penetration. Mode A-100 nominal.
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Time of flame appearance versus start of diffusion-controlled combustion
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GFL, area, WFL and ROHR versus angle. A-100.
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WFL and burnt gas temperature versus smoke at a crank angle where 75 percent of the total heat has been released
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ISoot emissions versus burnt gas temperature at 75 percent of heat released. Set 1 (hollow symbols, solid line). Set 2 (filled symbols, dashed line).
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Flame just before end of injection; (a) C-100, nominal conditions (b) A-100, late SOI, low IP



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