Comparison of Different Boosting Strategies for Homogeneous Charge Compression Ignition Engines - A Modeling Study

Mamalis, Sotirios; Nair, Vishnu G.; Andruskiewicz, Peter; Assanis, Dennis N.; Babajimopoulos, Aristotelis; Wermuth, Nicole; Najt, Paul

doi:10.4271/2010-01-0571

Cited by 22 publications

(14 citation statements)

References 22 publications

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“…The intake and exhaust manifold absolute pressures are set at 1, 1.5 and 2 bar for the boost sweep. For turbocharged HCCI, the exhaust manifold pressures are typically much greater than the intake manifold pressures; 11–14 however, this work makes a modeling simplification by setting the intake and exhaust pressures equal to each other. The amount of fuel injected is increased with boost to hold the mixture composition constant in terms of fuel-to-oxygen equivalence ratio ( ϕ FO ), fuel-to-charge equivalence ratio ( ϕ ′ ), residual gas fraction (RGF) and oxygen mole percentage ( χ O 2 ).…”

Section: Boost Sweep—simulation and Resultsmentioning

confidence: 99%

“…9 In addition to experimental studies, 6–9 a number of simulation studies have been performed to assess the requirements of boosted HCCI turbomachinary. 10–14 Typically, boosted HCCI demands higher intake pressures at similar conditions than conventional engines due to greater dilution required to beat the NOx emission limit. 7 On the other hand, intake boost for turbocharged HCCI comes at a significant pumping penalty.…”

Section: Introductionmentioning

confidence: 99%

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The effects of boost pressure on stratification and burn duration of gasoline homogeneous charge compression ignition combustion

Shingne

Middleton

Borgnakke

et al. 2018

International Journal of Engine Research

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This article investigates the effects of intake pressure (boost) on the pre-ignition stratification and burn duration of homogeneous charge compression ignition combustion. Full cycle computational fluid dynamics simulations are performed with gasoline kinetics. An intake pressure sweep is performed while maintaining the same combustion timing and mean composition. The burn duration reduces with increasing boost, even though intake temperature is reduced to hold combustion timing constant. It is shown that the compositional stratification increases with boost whereas thermal stratification decreases. A quasi-dimensional model is employed to assess the effect of compositional stratification, pressure, mean temperature and isolate the effect of thermal stratification on burn duration. The analysis reveals that reducing charge temperature neutralizes the effect of increased boost on reactivity and the shorter burn durations at higher boost are primarily due to the lower thermal stratification. It is shown that higher pressures do not significantly increase the mixing and the lower thermal stratification is due to lower wall heat losses per unit charge mass. A follow-up set of non-reacting simulations with adiabatic walls corroborate this claim by revealing a constant magnitude of thermal stratification across the boost sweep.

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Section: Boost Sweep—simulation and Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The effects of boost pressure on stratification and burn duration of gasoline homogeneous charge compression ignition combustion

Shingne

Middleton

Borgnakke

et al. 2018

International Journal of Engine Research

View full text Add to dashboard Cite

show abstract

“…Mamalis et al 1,8 have presented detailed literature reviews in previous publications regarding VVA and boosting for HCCI engines. Some key findings will be summarized here for completeness.…”

Section: Vva and Boostingmentioning

confidence: 99%

The interaction between compression ratio, boosting and variable valve actuation for high load homogeneous charge compression ignition: A modeling study

Mamalis

Babajimopoulos

Güralp

et al. 2014

International Journal of Engine Research

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This study discusses a novel approach toward homogeneous charge compression ignition operation in the 5 -10 bar net indicated mean effective pressure range. This approach is based on the combination of boosting and variable valve actuation to maximize engine efficiency. Compression ratio plays a key role and determines low-temperature combustion feasibility in modern gasoline compression ignition concepts. In order to explore the interactions between compression ratio, boosting system and variable valve actuation, multi-cylinder engine models were utilized which employed the University of Michigan combustion model. Valve strategies featured switching from low-lift negative valve overlap to high-lift positive valve overlap, and the switching point was found to be dependent on compression ratio. A recent study by the authors suggested that heating the charge from external compression is more efficient than heating by residual gas retention strategies. Use of non-cooled intake air allows for valve events and combustion phasing that promote turbocharger performance and alleviate the backpressure problems often associated with low temperature combustion engines. Elevated intake pressure and reduced pumping work allow for improvements in efficiency with minimal NOx formation and acceptable ringing. It was found that further efficiency benefits can be realized by increasing compression ratio. Identification of trade-offs between engine hardware and combustion mode appears to be critical for homogeneous charge compression ignition operation in the 5 -10 bar net indicated mean effective pressure range. By focusing on this operating range, the present modeling study attempts to shed some light on practical applications of light-duty gasoline compression ignition concepts.

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“…A study of boosting strategies for HCCI performed by Mamalis, et al, [14] concluded that a staged turbocharger system extends the load range at 2000 rev/m. The additional pumping work of the boost system reduced the brake efficiency, however.…”

Section: Introductionmentioning

confidence: 98%

Boost System Development for Gasoline Direct-Injection Compression-Ignition (GDCI)

Hoyer

Sellnau

Sinnamon

et al. 2013

SAE Int. J. Engines

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Intake boosting is an important method to improve fuel economy of internal combustion engines. Engines can be down-sized, down-speeded, and up-loaded to reduce friction losses, parasitic losses, and pumping losses, and operate at speed-load conditions that are thermodynamically more efficient. Low-temperature combustion engines (LTE) also benefit from down-sizing, down-speeding, and up-loading, but these engines exhibit very low exhaust enthalpy to drive conventional turbochargers. This paper describes modeling, evaluation, and selection of an efficient boost system for a 1.8L four-cylinder Gasoline Direct-Injection Compression-Ignition (GDCI) engine.After a preliminary concept selection phase the model was used to develop the boost system parameters to achieve fullload and part-load engine operation objectives. The simulation was used to demonstrate that a practical boost system can provide the boost necessary at reasonable brake efficiency levels over the entire engine operating range. A comprehensive simulation based calibration was performed to determine the most efficient steady operation settings. Also a step change in speed/load engine operation was simulated to demonstrate the system transient response.

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Comparison of Different Boosting Strategies for Homogeneous Charge Compression Ignition Engines - A Modeling Study

Cited by 22 publications

References 22 publications

The effects of boost pressure on stratification and burn duration of gasoline homogeneous charge compression ignition combustion

The effects of boost pressure on stratification and burn duration of gasoline homogeneous charge compression ignition combustion

The interaction between compression ratio, boosting and variable valve actuation for high load homogeneous charge compression ignition: A modeling study

Boost System Development for Gasoline Direct-Injection Compression-Ignition (GDCI)

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