Design of a Hybrid Power Unit for Formula SAE Application: Packaging Optimization and Thermomechanical Design of the Electric Motor Case

Mangeruga, Valerio; Giacopini, Matteo; Barbieri, Saverio Giulio; Berni, Fabio; Mattarelli, Enrico; Rinaldini, Carlo Alberto

doi:10.4271/2019-24-0197

Cited by 13 publications

(5 citation statements)

References 17 publications

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“…19 In this complex scenario, CFD tools play a fundamental role to reduce development costs and time to market. They can be proficiently adopted to estimate engine efficiency, optimize injection 20 and cooling strategies, 21,22 investigate alternative combustion 23,24 and ignition technologies, 25 evaluate the effect of water injection, [26][27][28][29] prevent knock [30][31][32] and thermomechanical failures 33 and, finally, predict tailpipe emissions. 34 In the light of the restrictive regulations in terms of pollution and the consequent efforts by the car manufacturers, in the last decade the CFD codes (especially 3D ones) have undergone a massive development to offer improved modeling for gaseous and, mostly, solid pollutants.…”

Section: Introductionmentioning

confidence: 99%

Modeling of gaseous emissions and soot in 3D-CFD in-cylinder simulations of spark-ignition engines: A methodology to correlate numerical results and experimental data

Berni

Pessina

Paltrinieri

et al. 2022

International Journal of Engine Research

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In order to reduce development costs and time-to market, 1D and 3D CFD tools can support engine design providing reliable estimations of the tailpipe emissions. In particular, 3D-CFD in-cylinder simulations can evaluate formation of both soot and gaseous pollutants inside the combustion chamber. The main issue in such kind of simulations is the validation against experimental findings. In fact, the complexity of the emission measurements does not allow a straightforward one-to-one comparison between numerical and experimental results. Therefore the present paper aims at providing, on the one hand, a robust numerical framework for both gaseous and solid emissions, on the other hand a dedicated post-processing for a fair comparison between simulations and experiments. From a numerical standpoint, a simplified approach is dedicated to gaseous emissions, while a more detailed one is reserved to soot modeling. The latter is based on the Sectional Method, whose reaction rates are tabulated following 0D chemical kinetic simulations of a purposely designed surrogate in a constant pressure reactor. Simulations and experiments proposed in the present analysis are referred to a high-performance turbocharged direct-injection spark-ignition engine operated at part-load and low rpms. On equal performance, revving speed and mean mixture quality, different injection timings are investigated. The developed numerical approach and post-processing ensure a good agreement between simulations and experiments.

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Section: Introductionmentioning

confidence: 99%

Modeling of gaseous emissions and soot in 3D-CFD in-cylinder simulations of spark-ignition engines: A methodology to correlate numerical results and experimental data

Berni

Pessina

Paltrinieri

et al. 2022

International Journal of Engine Research

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“…Alternative fuels, innovative combustion processes and aftertreatment systems are the predominant research fields to further develop Internal Combustion Engines (ICEs) amid the propulsion system innovation process. While waiting for mass-market penetration of alternative mobility solutions such as BEVs and FCEVs [1] [2], ICEs are still populating the large majority of passenger cars, although in the form of hybrid powertrains [3]. Among the ICEs, Direct Injection Spark Ignition (DISI) units must meet challenging and strict targets for the emissions, including Particulate Matter (PM) and Particle Number (PN).…”

Section: Introductionmentioning

confidence: 99%

Effect of Lagrangian-phase Modelling on Charge Stratification and Spatial Distribution of Threshold Soot Index for Toluene Reference Fuel Surrogates

Pessina

Borghi

2021

E3S Web Conf.

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Nowadays, soot emissions are one of the major concerns in Direct Injection Spark Ignition engines. Soot prediction models can be computationally expensive, especially when particle mass, number, and size distribution are to be forecast. While soot formation heavily depends on the chemical and physical characteristics of the fuel, the simulation of the exact composition of a real gasoline is computationally unfeasible. Thus, it is essential to find simplified yet representative pathways to reduce the computational cost of the simulations. On the one hand, the a-priori investigation of the factors influencing particulate onset can be a simplified approach to compare different solutions and strategies with much cheaper costs than the modelling of soot formation and oxidation mechanisms. On the other hand, the use of surrogate fuels is a practical approach to cope with the fuel chemical nature. Although they poorly mimic the evaporation properties of a real gasoline, Toluene Reference Fuels are broadly adopted to match combustion relevant properties of the real fuels. In this study, the spatial distribution of the Threshold Soot Index in the fluid domain is investigated for three surrogates characterized by an increasing content of toluene (0 mol%, 30 mol%, 60 mol%). The correlation between the sooting tendency and the fuel distribution in the combustion chamber before spark ignition time can provide useful preliminary indications, without spending the computational effort of the whole soot model multicycle resolution. In particular, two approaches for the lagrangian description of the injected fuel are investigated: a multicomponent approach and a single component one, this last driven by a high-fidelity lumped modelling of the surrogate properties for both liquid and vapor phase.

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“…Problems related to electric energy production, storage and distribution, battery raw materials and lifecycle, recharging time and driving autonomy are still long to be solved, hence the most viable immediate option for a cleaner mobility is hybridization. 1,2 A hybrid vehicle is a complex system where the thermal and electric energy sources are proficiently combined, taking advantage of both. Issues related to electric energy storage and range can be partially overcome thanks to the internal combustion engine (ICE), while tailpipe emissions can be cut down thanks to the development of ad-hoc combustion technologies and strategies.…”

Section: Introductionmentioning

confidence: 99%

Combustion modelling of turbulent jet ignition in a divided combustion chamber

Olcuire

Iacovano

D'Adamo

et al. 2021

International Journal of Engine Research

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Turbulent jet ignition is seen as one of the most promising strategies to achieve stable lean-burn operation in modern spark-ignition engines thanks to its ability to promote rapid combustion. A nearly stoichiometric mixture is ignited in a small-volume pre-chamber, following which multiple hot turbulent jets are discharged in the main chamber to initiate combustion. In the present work, a detailed computational investigation on the turbulent combustion regime of premixed rich propane/air mixture in a quiescent divided chamber vessel is carried out, to study the characteristics of the jet flame without the uncertainties in mixing and turbulent conditions typical of real-engine operations. In particular, the paper investigates the dependency of flame propagation on nozzle diameter (4, 6, 8, 12 and 14 mm) and pre-chamber/main-chamber volume ratio (10% and 20%); CFD results are compared to the experimental outcomes. Results show that the combustion regime in the quiescent pre-chamber follows a well-stirred reaction mode, rendering the limitation in using conventional flamelet combustion models. Furthermore, due to the very high turbulence levels generated by the outflowing reacting jets, also the main chamber combustion develops in a well-stirred reactor type, confirming the need for a kinetics-based approach to combustion modelling. However, the picture is complicated by thickened flamelet conditions possibly being verified for some geometrical variations (nozzle diameter and pre-chamber volume). The results show a general good alignment with the experimental data in terms of both jet phasing and combustion duration, offering a renewed guideline for combustion simulations under quiescent and low Damköhler number conditions.

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Design of a Hybrid Power Unit for Formula SAE Application: Packaging Optimization and Thermomechanical Design of the Electric Motor Case

Cited by 13 publications

References 17 publications

Modeling of gaseous emissions and soot in 3D-CFD in-cylinder simulations of spark-ignition engines: A methodology to correlate numerical results and experimental data

Modeling of gaseous emissions and soot in 3D-CFD in-cylinder simulations of spark-ignition engines: A methodology to correlate numerical results and experimental data

Effect of Lagrangian-phase Modelling on Charge Stratification and Spatial Distribution of Threshold Soot Index for Toluene Reference Fuel Surrogates

Combustion modelling of turbulent jet ignition in a divided combustion chamber

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