Optimal Heavy Fuel Direct Injection analysis in a Rotary Engine using a Computational Combustion Model

A nonlinear dynamic model is developed in this study to simulate the overall performance of a naturally aspirated, single cylinder, four-stroke, direct injection diesel engine under cold start and fully warmed-up conditions. The model considers the filling and emptying processes of the cylinder, blowby, intake, and exhaust manifolds. A single zone combustion model is implemented and the heat transfer in the cylinder, intake, and exhaust manifolds are accounted for. Moreover, the derivations include the dynamics of the crank-slider mechanism and employ an empirical model to estimate the instantaneous frictional losses in different engine components. The formulation is coded in modular form whereby each module, which represents a single process in the engine, is introduced as a single block in an overall Simulink engine model. The numerical accuracy of the Simulink model is verified by comparing its results to those generated by integrating the engine formulation using IMSL stiff integration routines. The engine model is validated by the close match between the predicted and measured cylinder gas pressure and engine instantaneous speed under motoring, steady-state, and transient cold start operating conditions.

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Effects of the Injection Parameters on the Emissions of a Heavy Duty Diesel Engine

Volume 3: Combustion Science and Engineering ◽

10.1115/imece2009-13222 ◽

2009 ◽

Author(s):

M. Yılmaz ◽

M. Zafer Gul ◽

Y. Yukselenturk ◽

B. Akay ◽

H. Koten

Keyword(s):

Diesel Engine ◽

Direct Injection ◽

Combustion Process ◽

Design Parameters ◽

Combustion Model ◽

Particulate Emissions ◽

Multiphase Model ◽

Heavy Duty ◽

Flow Development ◽

Air Motion

It is estimated by the experts in the automotive industry that diesel engines on the transport market should increase within the years to come due to their high thermal efficiency coupled with low carbon dioxide (CO2) emissions, provided their nitrogen oxides (NOx) and particulate emissions are reduced. At present, adequate after-treatments, NOx and particulates matter (PM) traps are developed and industrialized with still concerns about fuel economy, robustness, sensitivity to fuel sulfur and cost because of their complex and sophisticated control strategy. New combustion processes focused on clean diesel combustion are investigated for their potential to achieve near zero particulate and NOx emissions. Their main drawbacks are increased level of unburned hydrocarbons (HC) and carbon monoxide (CO) emissions, combustion control at high load and limited operating range and power output. In this work, cold flow simulations for a single cylinder of a nine-liter (6 cylinder × 1.5 lt.) diesel engine have been performed to find out flow development and turbulence generation in the piston-cylinder assembly. In this study, the goal is to understand the flow field and the combustion process in order to be able to suggest some improvements on the in-cylinder design of an engine. Therefore combustion simulations of the engine have been performed to find out flow development and emission generation in the cylinder. Moreover, the interaction of air motion with high-pressure fuel spray injected directly into the cylinder has also been carried out. A Lagrangian multiphase model has been applied to the in-cylinder spray-air motion interaction in a heavy-duty CI engine under direct injection conditions. A comprehensive model for atomization of liquid sprays under high injection pressures has been employed. The combustion is modeled via a new combustion model ECFM-3Z (Extended Coherent Flame Model) developed at IFP. Finally, a calculation on an engine configuration with compression, spray injection and combustion in a direct injection Diesel engine is presented. Further investigation has also been performed in-cylinder design parameters in a DI diesel engine that result in low emissions by effect of high turbulence level. The results are widely in agreement qualitatively with the previous experimental and computational studies in the literature.

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Ozone-Assisted Combustion—Part I: Literature Review and Kinetic Study Using Detailed n-Heptane Kinetic Mechanism

Journal of Engineering for Gas Turbines and Power ◽

10.1115/1.4027068 ◽

2014 ◽

Vol 136 (9) ◽

Cited By ~ 7

Author(s):

Christopher Depcik ◽

Michael Mangus ◽

Colter Ragone

Keyword(s):

Ignition Delay ◽

Equivalence Ratio ◽

Atomic Oxygen ◽

Direct Injection ◽

Kinetic Mechanism ◽

Combustion Model ◽

Ozone Decomposition ◽

Compression Ignition ◽

Review Of The Literature ◽

Compression Ignition Engine

In this first paper, the authors undertake a review of the literature in the field of ozone-assisted combustion in order to summarize literature findings. The use of a detailed n-heptane combustion model including ozone kinetics helps analyze these earlier results and leads into experimentation within the authors' laboratory using a single-cylinder, direct-injection compression ignition engine, briefly discussed here and in more depth in a following paper. The literature and kinetic modeling outcomes indicate that the addition of ozone leads to a decrease in ignition delay, both in comparison to no added ozone and with a decreasing equivalence ratio. This ignition delay decrease as the mixture leans is counter to the traditional increase in ignition delay with decreasing equivalence ratio. Moreover, the inclusion of ozone results in slightly higher temperatures in the cylinder due to ozone decomposition, augmented production of nitrogen oxides, and reduction in particulate matter through radial atomic oxygen chemistry. Of additional importance, acetylene levels decrease but carbon monoxide emissions are found to both increase and decrease as a function of equivalence ratio. This work illustrates that, beyond a certain level of assistance (approximately 20 ppm for the compression ratio of the authors' engine), adding more ozone has a negligible influence on combustion and emissions. This occurs because the introduction of O3 into the intake causes a temperature-limited equilibrium set of reactions via the atomic oxygen radical produced.

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Combined effect of injection timing and injection angle on mixture formation and combustion process in a direct injection (DI) natural gas rotary engine

Energy ◽

10.1016/j.energy.2017.04.052 ◽

2017 ◽

Vol 128 ◽

pp. 519-530 ◽

Cited By ~ 28

Author(s):

Baowei Fan ◽

Jianfeng Pan ◽

Wenming Yang ◽

Zhenhua Pan ◽

Stephen Bani ◽

...

Keyword(s):

Natural Gas ◽

Direct Injection ◽

Combustion Process ◽

Combined Effect ◽

Injection Timing ◽

Mixture Formation ◽

Injection Angle ◽

Rotary Engine

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Simulations of Multi-Mode Combustion Regimes Realizable in a Gasoline Direct Injection Engine

ASME 2020 Internal Combustion Engine Division Fall Technical Conference ◽

10.1115/icef2020-2940 ◽

2020 ◽

Author(s):

Sayop Kim ◽

Riccardo Scarcelli ◽

Yunchao Wu ◽

Johannes Rohwer ◽

Ashish Shah ◽

...

Keyword(s):

Mixed Mode ◽

Direct Injection ◽

Flow Property ◽

Gasoline Direct Injection ◽

Combustion Model ◽

Compression Ignition ◽

Fuel Blend ◽

Combustion Dynamics ◽

Low Load ◽

Multi Mode

Abstract Lean and dilute gasoline compression ignition (GCI) operation in spark ignition (SI) engines are an attractive strategy to attain high fuel efficiency and low NOx levels. However, this combustion mode is often limited to low-load engine conditions due to the challenges associated with autoignition controllability. In order to overcome this constrain, multi-mode (MM) operating strategies, consisting of advanced compression ignition (ACI) at low load and conventional SI at high load, have been proposed. In this 3-D CFD study the concept of multi-mode combustion using two RON98 gasoline fuel blends (Co-Optima Alkylate and E30) in a gasoline direct injection (GDI) engine were explored. To this end, a new reduced mechanism for simulating the kinetics of E30 fuel blend is introduced in this study. To cover the varying engine load demands for multi-mode engines, primary combustion dynamics observed in ACI and SI combustion modes was characterized and validated against experimental measurements. In order to implement part-load conditions, a strategy of mode-transition between SI and ACI combustion (i.e., mixed-mode combustion) was then explored numerically by creating a virtual test condition. The results obtained from the mixed-mode simulations highlight an important feature that deflagrative flame propagation regime coexists with ignition-assisted end-gas autoignition. This study also identifies a role of turbulent flow property adjacent to premixed flame front in characterizing the mixed-mode combustion. The employed hybrid combustion model was verified to perform simulations aiming at suitable range of multi-mode engine operations.

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Effect of Piston Crevices on 3D Simulation of a Heavy-Duty Diesel Engine Retrofitted to Natural Gas Spark Ignition

Volume 6A: Energy ◽

10.1115/imece2018-87783 ◽

2018 ◽

Cited By ~ 4

Author(s):

Iolanda Stocchi ◽

Jinlong Liu ◽

Cosmin E. Dumitrescu ◽

Michele Battistoni ◽

Carlo Nazareno Grimaldi

Keyword(s):

Fuel Injection ◽

Direct Injection ◽

Combustion Model ◽

Heavy Duty ◽

Ic Engine ◽

Pressure Trace ◽

Heavy Duty Diesel Engine ◽

Heavy Duty Diesel ◽

Flame Behavior ◽

Experimental Pressure

3D CFD IC engine simulations that use a simplified combustion model based on the flamelets concept can provide acceptable results with minimum computational costs and reasonable running times. More, the simulation can neglect small combustion chamber details such as valve crevices, valve recesses and piston crevices volume. The missing volumes are usually compensated by changes in the squish volume (i.e., by increasing the clearance height of the model compared to the real engine). This paper documents some of the effects that such an approach would have on the simulated results of the combustion phenomena inside a conventional heavy-duty direct-injection CI engine, which was converted to port-fuel injection SI operation. 3D IC engine simulations with or without crevice volumes were run using the G-equation combustion model. A proper parameter choice ensured that the simulation results agreed well with the experimental pressure trace. The results show that including the crevice volume affected the mass of unburned mixture inside the squish region, which in turn influenced the flame behavior and heat release during late-combustion stages.

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