Lean-Stratified Combustion System with Miller Cycle for Downsized Boosted Application - Part I

Solomon, Arun; Battiston, Paul A.; Sczomak, David P.

doi:10.4271/2021-01-0458

Cited by 11 publications

(4 citation statements)

References 21 publications

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“…Further efficiency enhancements of the gasoline Spark Ignition (SI) engine, which currently dominates the global light-duty vehicle segment, generally involves lean-burn operation, as lean combustion (using air-to-fuel ratios higher than the stoichiometric ratio, i.e., λ > 1) and high compression ratios are well known to improve the efficiency of gasoline SI engines [82]. In e.g., combining lean combustion and Variable Valve Timing (VVT) Miller cycle technology at low-to-medium loads and homogeneous stoichiometric operation at higher loads, an improvement in Brake-Specific Fuel Consumption (BSFC) of > 30% under lean conditions over the all-stoichiometric operation has been demonstrated [83,84]. [78][79][80]).…”

Section: Transportationmentioning

confidence: 99%

Materials Design for the Improvement of SiC Field Effect Gas Sensor performance in High Temperature Process Control applications

Khajavizadeh

2023

Linköping Studies in Science and Technology. Dissertations

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Section: Transportationmentioning

confidence: 99%

Materials Design for the Improvement of SiC Field Effect Gas Sensor performance in High Temperature Process Control applications

Khajavizadeh

2023

Linköping Studies in Science and Technology. Dissertations

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“…Until then, there are several opportunities to improve the efficiency of current transportation systems, i.e., internal combustion engines. These can be summarized but are not limited to combustion improvement [3,4], use of biofuels [5], Waste Heat Recovery (WHR) systems [6][7][8], and engine downsizing [9]. This latter is particularly relevant regarding mechanical efficiency improvement, the reduction of parasitic loss [10] and the decrease of propulsion power.…”

Section: Introductionmentioning

confidence: 99%

Theoretical and experimental evaluation of electric coolant pump benefits in real driving cycles

Marco,

Davide,

Roberto

2023

J. Phys.: Conf. Ser.

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Engine thermal management is a promising option to reduce fuel consumption and harmful emissions of Internal Combustion Engines. This is particularly suitable to support the transition towards a carbon-neutral transportation sector, considering that the role of combustion engines is expected to persist in the near and medium future. In this study, a prototype pump electrically actuated was compared to a mechanical pump of a downsized gasoline engine that propels a real vehicle. In the first phase of the analysis, the cooling circuit was tested from a hydraulic point of view on all its branches using an engine mounted on a bench equal to that working on the vehicle. The hydraulic circuit was fully characterized via pressure transducers and flow meters in all branches for different thermostat lifts, representing different coolant temperatures. On the same bench, the OEM pump and an electrically actuated one, suitably redesigned on an operating point more representative of the real operating conditions, were tested. A vehicle propelled with the same tested engine (having a conventional mechanically actuated pump) was run on the road following three different driving cycles. The engine revolution speeds were registered, as well as the temperature of the cooling fluid. The electric and mechanical pumps were compared using the performance maps previously obtained. The electric pump speed was set to deliver the same coolant flow rate as the OEM pump, following the same sequence of thermostat lifts. The results show that a 60 % average reduction of the pump energy consumption is possible, leading to an average specific CO2 emission reduction of 1 g/km. This result is even more relevant during urban driving, with emission savings hitting 2.5 g/km.

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“…The spark-ignition (SI) engine represents one of the most interesting and feasible solutions in powertrain technologies to meet such ambitious targets. Currently, SI engines are under continuous improvement to achieve ever increasing thermal efficiencies as well as near-zero pollutant emissions [5][6][7]. In this framework, the major challenge is to operate the engine with homogeneous ultra-lean premixed (HULP) mixtures, which have the potential to minimize thermal losses, avoid soot formation and cut NO x emissions, paving the way for a further reduction in size and costs of the after-treatment system [8,9].…”

Section: Introductionmentioning

confidence: 99%

Ultra-Lean Premixed Turbulent Combustion: Challenges of RANS Modelling

et al. 2022

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The main challenge of improving spark ignition (SI) engines to achieve ever increasing thermal efficiencies and near-zero pollutant emissions today concerns developing turbulent combustion under homogeneous ultra-lean premixed mixtures (HULP). This continuous shift of the lean operation limit entails questions on the applicability limits of the combustion models used to date for SI engine design and optimization. In this work, an assessment of flamelet-based models, widely used in RANS SI engines simulations of premixed turbulent combustion, is carried out using an open-source 3D-CFD platform to clarify the applicability limits on HULP mixtures. Two different consolidated approaches are selected: the Coherent Flame Model (CFM) and the Flame Area Model (FAM). Both methodologies are embedded by the authors into the same numerical structure and compared against measurements over a simplified and controlled flame configuration, which is representative of engine-like conditions. The experimental steady-state flame of type “A” of the Darmstadt Turbulent Stratified Flame (TSF) burner is selected for the assessment. This configuration is characterized by flame measurements over a strong shear and mixing layer between the central high-speed CH4-air jet and the surrounding slow air co-flow, hence, it represents an interesting controlled condition to study turbulent HULP mixtures. A comparison between computed results and experimental data on trends of mean flow velocity, turbulence, temperature and mixture stratification was carried out. This enabled us to assess that the investigated flamelet-based combustion models failed in providing accurate and reliable results when the flame approaches turbulent HULP mixture conditions, demonstrating the urgency to develop models able to fill this gap.

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Lean-Stratified Combustion System with Miller Cycle for Downsized Boosted Application - Part I

Cited by 11 publications

References 21 publications

Materials Design for the Improvement of SiC Field Effect Gas Sensor performance in High Temperature Process Control applications

Materials Design for the Improvement of SiC Field Effect Gas Sensor performance in High Temperature Process Control applications

Theoretical and experimental evaluation of electric coolant pump benefits in real driving cycles

Ultra-Lean Premixed Turbulent Combustion: Challenges of RANS Modelling

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