Some aspects concerning the combination of downsizing with turbocharging, variable compression ratio, and variable intake valve lift

Clenci, Adrian; Descombes, Georges; Podevin, Pierre; Hara, V

doi:10.1243/09544070jauto449

Cited by 44 publications

(33 citation statements)

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“…Lake et al [2] examined the potential of reducing engine swept volume to meet the future tighter requirement of CO 2 reduction, and they proposed a promising concept, termed lean burn direction injection (LBDI), to control octane requirement while maintaining a high compression ratio (CR). Clenci et al [3] conducted the analysis on the effects of engine downsizing on the fuel economy. In automotive SI engines, the most frequent operations are at partial loads and the load control is usually implemented by using a throttle valve to restrict airflow into cylinders, which results in pumping loss during gas exchange strokes.…”

Section: Introductionmentioning

confidence: 99%

A comparison between Miller and five-stroke cycles for enabling deeply downsized, highly boosted, spark-ignition engines with ultra expansion

Wang

Zheng

2016

Energy Conversion and Management

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Section: Introductionmentioning

confidence: 99%

A comparison between Miller and five-stroke cycles for enabling deeply downsized, highly boosted, spark-ignition engines with ultra expansion

Wang

Zheng

2016

Energy Conversion and Management

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“…Nevertheless, this gap can be reduced by the use of different technical solutions: lean burn and stratified-charge gasoline direct injection-GDI, variable valve actuation-VVA, variable compression ratio-VCR, Downsizing, Atkinson-Miller cycle, some of them already applied in mass production [1][2][3][4][5][6][7][8][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

“…For this purpose, an original VVA engine prototype was used. Its VVA mechanism is able to adjust the intake valve lift continuously between minimum and maximum values during engine operation [5,6,11,23], see Figure 1 and Appendix. …”

Section: Introductionmentioning

confidence: 99%

Idle Operation with Low Intake Valve Lift in a Port Fuel Injected Engine

Clenci

Bîzîiac²,

Podevin

et al. 2013

Energies

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Abstract:Reducing fuel consumption is a prime objective in the automotive industry in order to meet regulatory and customer demands. Variable valve actuation offers many opportunities for improving the spark ignition engine's performance in areas such as fuel economy and pollutant emissions. Our studies revealed that the ability to control maximum intake valve lift does indeed offer the ability to control intake air mass, but also has the added benefit that it improves the fuel-air mixing process thanks to an increased turbulence, caused by the increased intake flow velocity. This is particularly important at idle and low part loads when low maximum lifts are to be used for improving the fuel economy or for achieving the required power. The paper focuses on the experimental results obtained when approaching idle operation with different intake valve laws. Results indicating the potential of using low intake valve lift for fuel economy and cyclic dispersion improvement are presented in this paper.

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“…The variable compression ratio (VCR) is an ideal method to suppress knocking, however, the structural complexity of the VCR significantly increases the cost. [5]. Cooled exhaust gas recirculation (EGR) is another promising method [6,7], but the engine system becomes complicated and the power density will be reduced for the same hardware.…”

Section: Introductionmentioning

confidence: 99%

Knocking Suppression by Stratified Stoichiometric Mixture With Two-Zone Homogeneity in a DISI Engine

Bai¹,

Wang²,

Wang³

et al. 2012

Journal of Engineering for Gas Turbines and Power

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Knocking Suppression by Stratified Stoichiometric iVIixture With Two-Zone Homogeneity in a DISI EngineKnocking is the main obstacle of increasing the compression ratio in order to improve the thermal efficiency of gasoline engines. This paper proposes a concept of a stratified stoichiometric mixture (SSM) with two-zone homogeneity (TZH)for suppressing knocking and validated the concept by means of a numerical simulation and an experimental study in a DISI engine. The results show that the SSM can effectively suppress knocking and the knocking intensity decreases when the zone around the spark plug is richer and the end-gas zone is leaner. The less rich zone (fuel/air equivalent ratio of (¡)<1.2) of the SSM can speed up the initial burning velocity in order to avoid a thermal efficiency decrease, while the over rich zone ((¡>>1.2) would decrease the combustion velocity when knocking was suppressed. The SSM leads to higher CO and lower HC and NOê missions, which can be effectively after-treated using a three-way catalyst. The SSM can also reduce the decrease of power output compared to the method of retarding spark timing for suppressing knocking and has better fuel economy and fewer emissions than the method of enriching the mixture. The TZH can effectively alleviate combustion deterioration and soot formation due to the stratified mixture combustion. As a result, the SSM with TZH suppresses knocking, thus simultaneously lowering fuel consumption and emissions.

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Some aspects concerning the combination of downsizing with turbocharging, variable compression ratio, and variable intake valve lift

Cited by 44 publications

References 1 publication

A comparison between Miller and five-stroke cycles for enabling deeply downsized, highly boosted, spark-ignition engines with ultra expansion

A comparison between Miller and five-stroke cycles for enabling deeply downsized, highly boosted, spark-ignition engines with ultra expansion

Idle Operation with Low Intake Valve Lift in a Port Fuel Injected Engine

Knocking Suppression by Stratified Stoichiometric Mixture With Two-Zone Homogeneity in a DISI Engine

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