Abstract
The oxygen-depleted environment in the recompression stroke can convert gasoline fuel into light hydrocarbons due to thermal cracking, partial oxidation, and water-gas shift reactions. These reformate species can influence the combustion characteristics of gasoline direct injection homogeneous charge compression ignition (GDI-HCCI) engines. In this work, the combustion phenomena are investigated using a single-cylinder research engine under a medium load. The main combustion phases are experimentally advanced by direct fuel injection into the negative valve overlap (NVO) compared with that of intake stroke under single/double-pulse injections. NVO peak in-cylinder pressures are lower than that of motoring due to the limited O2 concentration, emphasizing that endothermic reactions occur during the overlap. This phenomenon limits the oxidation reactions, and the thermal effect is not pronounced. The zero-dimensional chemical kinetics results present the same increasing tendencies of classical reformed species of rich mixture such as C3H6, C2H4, CH4, CO, and H2 as functions of injection timings. Predicted ignition delays are shortened due to the additions of these reformed species. The influences of the reformates on the main combustion are confirmed by three-dimensional computational fluid dynamics (CFD) calculations, and the results show that OH radicals are advanced under NVO injections relative to intake stroke injections. Consequently, earlier heat release and cylinder pressure are noticeable. Parametric studies on the effects of injection pressure, double-pulse injection, and equivalence ratio on the combustion and emissions are also discussed experimentally.
Issue Section:
Fuel Combustion
References
1.
Martinez-Frias
, J.
, Aceves
, S. M.
, Flowers
, D.
, Smith
, J. R.
, and Dibble
, R.
, 2002
, “Thermal Charge Conditioning for Optimal HCCI Engine Operation
,” ASME J. Energy Resour. Technol.
, 124
(1
), pp. 67
–75
. 10.1115/1.14479282.
Maurya
, R. K.
, and Agarwal
, A. K.
, 2015
, “Experimental Investigations of Particulate Size and Number Distribution in an Ethanol and Methanol Fueled HCCI Engine
,” ASME J. Energy Resour. Technol.
, 137
(1
), p. 012201
. 10.1115/1.40278973.
Urushihara
, T.
, Hiraya
, K.
, Kakuhou
, A.
, and Itoh
, T.
, 2003
, “Expansion of HCCI Operating Region by the Combination of Direct Fuel Injection, Negative Valve Overlap and Internal Fuel Reformation
,” SAE Technical Paper 2003-01-0749
.4.
Li
, H.
, Neill
, W. S.
, and Chippior
, W. L.
, 2012
, “An Experimental Investigation of HCCI Combustion Stability Using n-Heptane
,” ASME J. Energy Resour. Technol.
, 134
(2
), p. 022204
. 10.1115/1.40057005.
Yang
, J.
, Culp
, T.
, and Kenney
, T.
, 2002
, “Development of a Gasoline Engine System Using HCCI Technology—The Concept and the Test Results
,” SAE Technical Paper 2002-01-2832
.6.
Mamalis
, S.
, Babajimopoulos
, A.
, Guralp
, O.
, and Najt
, P.
, 2012
, “Optimal Use of Boosting Configurations and Valve Strategies for High Load HCCI—A Modeling Study
,” SAE Technical Paper 2012-01-1101
.7.
Szybist
, J.
, Edwards
, K.
, Foster
, M.
, Confer
, K.
, and Moore
, W.
, 2013
, “Characterization of Engine Control Authority on HCCI Combustion as the High Load Limit is Approached
,” SAE Int. J. Engines
, 6
(1
), pp. 553
–568
. 10.4271/2013-01-16658.
Szybist
, J.
, Steeper
, R.
, Splitter
, D.
, Kalaskar
, V.
, Pihl
, J.
, and Daw
, C.
, 2014
, “Negative Valve Overlap Reforming Chemistry in Low-Oxygen Environments
,” SAE Int. J. Engines
, 7
(1
), pp. 418
–433
. 10.4271/2014-01-11889.
Ratnak
, S.
, Kusaka
, J.
, Daisho
, Y.
, Yoshimura
, K.
, and Nakama
, K.
, 2018
, “Effect of Fuel Injection Timing During Negative Valve Overlap Period on a GDI-HCCI Engine
,” Proceedings of the ASME 2018 Internal Combustion Engine Division Fall Technical Conference. Volume 1: Large Bore Engines; Fuels; Advanced Combustion
, San Diego, CA
, Nov. 4–7
, p. V001T03A020
.10.
Borgqvist
, P.
, Tunestal
, P.
, and Johansson
, B.
, “Comparison of Negative Valve Overlap (NVO) and Rebreathing Valve Strategies on a Gasoline PPC Engine at Low Load and Idle Operating Conditions
,” SAE Int. J. Engines
, 6
(1
), pp. 366
–378
. 10.4271/2013-01-090211.
Badra
, J. A.
, Sim
, J.
, Elwardany
, A.
, Jaasim
, M.
, Viollet
, Y.
, Chang
, J.
, Amer
, A.
, and Im
, H. G.
, 2016
, “Numerical Simulations of Hollow-Cone Injection and Gasoline Compression Ignition Combustion With Naphtha Fuels
,” ASME J. Energy Resour. Technol.
, 138
(5
), p. 052202
. 10.1115/1.403262212.
Kavuri
, C.
, and Kokjohn
, S. L.
, 2018
, “Computational Study to Identify Feasible Operating Space for a Mixed Mode Combustion Strategy—A Pathway for Premixed Compression Ignition High Load Operation
,” ASME J. Energy Resour. Technol.
, 140
(8
), p. 082201
. 10.1115/1.403954813.
Kokjohn
, S.
, Hanson
, R.
, Splitter
, D.
, and Reitz
, R.
, 2010
, “Fuel Reactivity Controlled Compression Ignition (RCCI): A Pathway to Controlled High-Efficiency Clean Combustion
,” Int. J. Eng. Res.
, 12
(3
), pp. 209
–226
. 10.1177/146808741140154814.
Fang
, W.
, Fang
, J.
, Kittelson
, D. B.
, and Northrop
, W. F.
, 2015
, “An Experimental Investigation of Reactivity-Controlled Compression Ignition Combustion in a Single-Cylinder Diesel Engine Using Hydrous Ethanol
,” ASME J. Energy Resour. Technol.
, 137
(3
), p. 031101
. 10.1115/1.402877115.
Ratnak
, S.
, Kusaka
, J.
, Daisho
, Y.
, Yoshimura
, K.
, and Nakama
, K.
, 2016
, “Experiments and Simulations of a Lean-Boost Spark Ignition Engine for Thermal Efficiency Improvement
,” SAE Int. J. Engines
, 9
(1
), pp. 379
–396
.16.
Sok
, R.
, Yamaguchi
, K.
, and Kusaka
, J.
, 2021
, “Prediction of Ultra-Lean Spark Ignition Engine Performances by Quasi-Dimensional Combustion Model With a Refined Laminar Flame Speed Correlation
,” ASME J. Energy Resour. Technol.
, 143
(3
), p. 032306
. 10.1115/1.404912717.
Ekoto
, I.
, Peterson
, B.
, Szybist
, J.
, and Northrop
, W.
, 2015
, “Analysis of Thermal and Chemical Effects on Negative Valve Overlap Period Energy Recovery for low-Temperature Gasoline Combustion
,” SAE Int. J. Engines
, 8
(5
), pp. 2227
–2239
. 10.4271/2015-24-245118.
Arning
, J.
, Ramsander
, T.
, and Collings
, N.
, 2010
, “Analysis of In-Cylinder Hydrocarbons in a Multi-Cylinder Gasoline HCCI Engine Using Gas Chromatography
,” SAE Int. J. Engines
, 2
(2
), pp. 141
–149
. 10.4271/2009-01-269819.
Fitzgerald
, R.
, and Steeper
, R.
, 2010
, “Thermal and Chemical Effects of NVO Fuel Injection on HCCI Combustion
,” SAE Int. J. Engines
, 3
(1
), pp. 46
–64
. 10.4271/2010-01-016420.
Peterson
, B.
, Ekoto
, I.
, and Northrop
, W.
, 2015
, “Investigation of Negative Valve Overlap Reforming Products Using Gas Sampling and Single-Zone Modeling
,” SAE Int. J. Engines
, 8
(2
), pp. 747
–757
. 10.4271/2015-01-081821.
Manofsky
, L.
, Vavra
, J.
, Assanis
, D.
, and Babajimopoulos
, A.
, 2011
, “Bridging the Gap between HCCI and SI: Spark-Assisted Compression Ignition
,” SAE Technical Paper 2011-01-1179
.22.
Alger
, T.
, and Mangold
, B.
, 2009
, “Dedicated EGR: A New Concept in High Efficiency Engines
,” SAE Int. J. Engines
, 2
(1
), pp. 620
–631
. 10.4271/2009-01-069423.
Fogla
, N.
, Bybee
, M.
, Mirzaeian
, M.
, Millo
, F.
, and Wahiduzzaman
, S.
, “Development of a K-k-∊ Phenomenological Model to Predict In-Cylinder Turbulence
,” SAE Int. J. Engines
, 10
(2
), pp. 562
–575
. 10.4271/2017-01-054224.
Lutz
, A.
, Kee
, R.
, and Miller
, J.
, 1996
, “SENKIN: A Fortran Program for Predicting Homogeneous Gas Phase Chemical Kinetics With Sensitivity Analysis
”, Sandia National Lab
., Livermore, CA
.25.
ANSYS, Inc.
, 2018
, Forte Theory Manual, Release 19.0, Pennsylvania
.26.
Huang
, C.
, Golovitchev
, V.
, and Lipatnikov
, A.
, 2010
, “Chemical Model of Gasoline-Ethanol Blends for Internal Combustion Engine Applications
,” SAE Technical Paper 2010-01-0543
. 10.4271/2010-01-054327.
Curran
, H. J.
, Pitz
, W. J.
, Westbrook
, C. K.
, Callahan
, G. V.
, and Dryer
, F. L.
, 1998
, “Oxidation of Automotive Primary Reference Fuels at Elevated Pressures
,” Proc. Combust. Inst.
, 27
(1
), pp. 379
–387
. 10.1016/S0082-0784(98)80426-828.
29.
Kong
, S.
, and Reitz
, R. D.
, 2002
, “Use of Detailed Chemical Kinetics to Study HCCI Engine Combustion With Consideration of Turbulent Mixing Effects
,” ASME J. Eng. Gas Turbines Power
, 124
(3
), pp. 702
–707
. 10.1115/1.141376630.
Heywood
, J. B.
, 2018
, Internal Combustion Engine Fundamentals
, 2nd ed., McGraw-Hill
, New York
.31.
Sok
, R.
, 2015
, “A Study on a Lean-Boost Gasoline Engine Under SI and HCCI Combustion Modes
,” Waseda University Repository Doctoral thesis
, Waseda University
, Tokyo, Japan
.32.
Kaminaga
, T.
, Yamaguchi
, K.
, Ratnak
, S.
, Kusaka
, J.
, Youso
, T.
, Fujikawa
, T.
, and Yamakawa
, M.
, 2019
, “A Study on Combustion Characteristics of a High Compression Ratio SI Engine With High Pressure Gasoline Injection
,” SAE Technical Paper 2019-24-0106
. 10.4271/2019-24-010633.
Warnatz
, J.
, Mass
, U.
, and Dibble
, R. W.
, 2006
, Combustion-Physical and Chemical Fundamentals, Modeling and Simulation, Experiments, Pollutant Formation
, 2nd ed., Springer
, New York
, pp. 230
–231
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