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Electric Machines with Reconfigurable Windings for Automotive Applications

2025-24-0131To be published on 09/07/2025

The performance of electric machines for automotive applications is characterised by a high transient torque capability for low speed tractability and a large speed range of high energy conversion efficiency to achieve a desirable vehicle range. Inevitably, these conflicting requirements will introduce a compromise in the design process of electric machines and drives, generally resulting in heavier machines and overrated drive specifications. This paper will discuss the use of electric machines with reconfigurable windings for automotive applications. Reconfigurable windings allow an electric machine to switch between two or more different winding configurations, optimised for both high torque and high speed. Actively changing the armature winding connections of an electric machine can be leveraged to increase the torque density, power density, and extend the speed range of Permanent Magnet Synchronous Motors (PMSMs) without requiring further modifications to the machine geometries or

Best, Joshua, Noori Asiabar, Aria, Wang, Bo, Herzog, Matic, Trinchuk, Danylo, Romih, Jaka

Multi-Objective Optimization of the Energy Management Strategy for Hybrid Electric Vehicles - Examination of Sensitivities between Fuel Consumption, Electric Driving and Driving Comfort

2025-24-0103To be published on 09/07/2025

The combination of the electric drive and the internal combustion engine (ICE) in hybrid electric vehicles (HEV) requires the implementation of an Energy Management Strategy (EMS). The task of the EMS is to split the driving demand between the two energy converters. The design of the EMS in charge-sustaining operation is commonly targeted at the minimization of fuel consumption. For in-vehicle implementation of the EMS, supplementary objectives, such as the electric driving (ED) experience or the driving comfort, influenced by the frequency of state shifts, are considered. Therefore, this work extends the framework for EMS optimization from the fuel-optimal design to multi-objective target spaces. First, the general multi-objective optimal control problem (MOOCP) is formulated. In a next step the central target space for EMS calibration consisting of fuel consumption, ED time and number of ICE starts is considered and the resulting MOOCP is solved using Dynamic Programming (DP). The

Ehrenberg, Bastian

A Novel Chemical Kinetics-Based Approach for Studying Feasibility and Optimizing Retrofitting Strategies of CI Engines with Hydrogen: Application to a Laboratory-Scale Single-Cylinder Engine

2025-24-0054To be published on 09/07/2025

The climate emergency has prompted countries to adopt strategies to limit the rise in global temperatures by promoting low-carbon technologies. In this context, hydrogen (H2) can be considered a viable solution, especially in road and marine transportation, where Compression Ignition (CI) internal combustion engines (ICEs) are widely used. Despite its potential to significantly reduce pollutant emissions compared to fossil fuels, hydrogen presents a major challenge for CI engines due to its high autoignition temperature (greater than diesel). To overcome this problem, a novel methodology is proposed to evaluate the feasibility of hydrogen retrofitting. Each engine operating point is simulated as an ideal zero-dimensional (0D) reactor into which a diesel-hydrogen-air mixture is introduced. A fully detailed kinetic mechanism is used to simulate the complex chemical interactions between the two fuels, as well as its significant effect on engine behaviour, obtaining accurate predictions of

Episcopo, Domenico, Rossetti, Salvatore, Mancaruso, Ezio, Saponaro, Gianmarco, Camporeale, Sergio, Laera, Davide

Design of a Reconfigurable Winding Switch for an In-Wheel Automotive Motor

2025-24-0130To be published on 09/07/2025

A design is presented for a mechanical switchgear, intended for reconfiguring the windings of an electric machine whilst in operation. The design is a result of the EM-TECH project funded under Horizon Europe, and includes integration onto an in-wheel automotive motor. The motor features 6 phase fractions, which can be reconfigured by the switchgear between series-star or parallel-star arrangements, thereby doubling the torque or speed range of the electric machine. The effect on the operating envelope of the machine is similar to the addition of a 2-speed transmission, but with an added mass of only 1.5kg – around one tenth of the equivalent transmission. As well as the extended operating envelope, the reconfigurable winding motor offers benefits in efficiency and power density. Previous studies have shown the technical feasibility of such devices using semiconductor switches. Although these studies have confirmed the performance of the technology, such semiconductor solutions have

Vagg, Christopher, Thomas, Luke, Pickering, Simon, Herzog, Matic, Trinchuk, Danylo, Romih, Jaka

Modeling fuel consumption in a heavy-duty diesel truck under real-world driving conditions including cold-start operation

2025-24-0096To be published on 09/07/2025

Heavy-duty vehicles contribute significantly to global greenhouse gas emissions and are now facing challenges in meeting emission regulatory standards, with particular reference to cold-start operations. Advanced powertrains that make use of hybridization and waste heat recovery with phase-changing materials offer potential pathways to mitigate fuel consumption and emissions under real-world driving conditions. Still, they need to be accurately sized and managed to overcome the disadvantages of increased mass and complexity. This investigation paves the way for developing such advanced power systems by implementing a scalable map-based model for heavy-duty diesel engines. The model is validated using an open access data set related to a heavy-duty vehicle equipped with a 6-7L diesel engine performing 28 different trips on the same route with the same driver. The trips are performed with three different values of payload and contain both cold-start and hot-start operating conditions

Donateo, Teresa, Mujahid, Talha, Morrone, Pietropaolo, Algieri, Angelo

Advanced Plasma-based Ignition Strategy for Future Spark Ignition Engines

2025-24-0020To be published on 09/07/2025

Internal combustion engines will continue to play an important role in transportation for decades to come because of the high onboard energy density. For present passenger vehicles, efforts have been made to reduce the cold start emissions and improve engine efficiency. To reach such goals, lean and diluted mixtures are needed to reduce the chemical reactivity of the mixture, so a higher engine compression ratio can be used to improve thermal efficiency. The decreased flame temperature of the lean/diluted mixtures are also beneficial for NOx reduction. Strong in-cylinder flow is needed to increase flame propagation speed for efficient and complete combustion process. Strong ignition sources are needed to provide robust ignition to support the combustion process. In this paper, the application of advanced plasma-based ignition strategies are reviewed, with special attention to the on-demand plasma energy profiling, which has flexible control over discharge duration and current

Yu, Xiao, Leblanc, Simon, Reader, Graham, Zheng, Ming

Experimental measurement of dynamometer homologation cycles in a dual-fuel medium-duty engine

2025-24-0036To be published on 09/07/2025

Dual-fuel engines employing alternative combustion concepts have shown promising results in meeting significant emission reductions while maintaining engine performance. In the medium and heavy-duty transport sectors, where electrification remains challenging, developing low-temperature combustion is still a technological solution for reducing carbon impact. However, most of the results in this research field have been presented under stationary conditions, which still positions the transient operation as a challenge. One of the main reasons has been the lack of a dedicated control system to manage the load transitions and the inoperability of stock turbochargers to satisfy the EGR dilution ratios and boost pressure to sustain dual-fuel combustion. This study employs a modified 7.7 L dual-fuel engine for its operation in transient conditions by incorporating a prototype turbocharger system. The study addresses the recalibration of the engine to introduce modifications to the injection

Garcia, Antonio, Monsalve-Serrano, Javier, Marco-Gimeno, Javier, Iñiguez, Erasmo

Experimental Assessment of ‘Drop-in’ and ‘Optimized’ HVO usage in a 6.6l Diesel Engine for Low-emissions Marine Applications

2025-24-0073To be published on 09/07/2025

All mobility sectors are facing the challenge to contribute actively to the reduction of environmental pollution and of the impact on climate change driven by Greenhouse Gas effect. One of the most active sectors in the research of environment-friendly propulsion propositions is the recreational and light-commercial boating. Presently, many of the boats operating in this sector are propelled by internal combustion engines derived from road applications. In this work, the effects of replacing conventional fossil-derived B7 diesel with Hydrotreated Vegetable Oil (HVO) were experimentally investigated in a modern Medium-Duty Engine, using the advanced biofuel initially as drop-in replacement, and then repeating the testing after the recalibration of the engine combustion setpoints. Comparing the results of the replacement of diesel with HVO showed appreciable benefits in terms of NOx, Particulate Matter (PM), mass fuel consumption and Well-to-Wake (WtW) CO2 thanks to the inner properties

Cosseddu, Cinzia, Spedicato, Tonio, Pennazio, Davide, Vassallo, Alberto, Fittavolini, Corrado

Mid-IR Laser Extinction Measurement of Formaldehyde Emissions in a Methanol Mixing-Controlled Compression Ignition Engine

2025-24-0034To be published on 09/07/2025

As the energy security and sustainability becomes important and restrictions on carbon footprints grow stricter, the role of low-carbon alternative fuels, particularly methanol, is becoming increasingly significant. While the feasibility of methanol as a substitute for diesel fuel has been explored, understanding of emissions from methanol-fueled compression-ignition engines remains limited, even though these engines are known to emit formaldehyde (CH2O) due to methanol’s chemical structure and oxidation pathways. In this study, a quantitatively measurable mid-IR laser-based extinction methodology was employed to understand CH2O formation in a methanol mixing-controlled compression ignition engine. Stable methanol compression ignition combustion was achieved with the addition of 5%vol 2-ethylhexly nitrate and by using a triple injection strategy (pilot + pilot + main), and CH2O emissions were measured with high temporal resolution by laser extinction while sweeping the injection timing

Lee, Sanguk, Lopez Pintor, Dario, Narayanan, Abhinandhan

Numerical analysis of the combustion process in a pre-chamber marine engine fueled with ammonia-hydrogen mixtures

2025-24-0021To be published on 09/07/2025

Ammonia and hydrogen, as carbon-neutral fuels, possess the potential to play a crucial role in the decarbonization of the mobility sector. This research examines the optimization of the combustion process in a marine spark-ignition engine through the use of a passive pre-chamber. The study has been carried out using computational fluid dynamics (CFD) models. Considering a hydrogen content in the fuel blend of 15% by volume, at a fixed equivalence ratio equal to 0.8, two different nozzle diameters have been tested, and the optimal spark timings have been identified. Then, the effect of different hydrogen amounts in the fuel mixture on the engine’s performance and emissions has been assessed. An optimal spark timing of 712 CAD has been found for both 3 mm and 5 mm nozzles at the specified operating point. The 5 mm nozzle provides slightly higher IMEPH and gross efficiency, with minimal impact on emissions. Reducing hydrogen in the fuel blend from 15% to 10% lowers IMEPH from 31 to 12 bar

D'Antuono, Gabriele, Lanni, Davide, Galloni, Enzo, Fontana, Gustavo

Combined Virtual and Experimental Approach to Develop Highly Efficient Metallic Catalyst for New World Wide Emission Legislation

2025-24-0080To be published on 09/07/2025

The market penetration of Battery Electric Vehicles (BEV) in Europe is not following the foreseen scenario. This is related to several factors, such as uncertainty of the second-hand value of BEV, real driving range under cold conditions and availability of charging stations. Even if the European Community is still planning a full ban of Internal Combustion Engines (ICE) by 2035. In the rest of the world a more technology neutral approach is being pursued with car manufacturers developing different powertrain architectures, from mild- to full-hybrid and Range Extenders (REEX). In this context the different emission regulations, and the wide range of powertrain architectures, the focus of the development will be the increase of catalyst efficiency without any big impact on exhaust aftertreatment cost. In this work the authors have used a 1D simulation approach to support the optimization of metallic TWC substrate for the High Power Cold Start use case. Additionally, a 3D CFD was used

Montenegro, Gianluca, Della Torre, Augusto, Marinoni, Andrea, Onorati, Angelo, Klövmark, Henrik, Laurell, Mats, Pace, Lorenzo, Konieczny, Katrin

Calorimetric study of the influence of spark ignition system parameters on the energy transfer to the gas

2025-24-0033To be published on 09/07/2025

This paper presents novel studies on how different ignition control parameters, spark plug geometries, and gas pressure interplay in energy transfer from spark to gas. The experiments are conducted in a 10.9 milliliter custom-built spark calorimeter. An inert non-combustible gas – Nitrogen is used as a fluid in the chamber. An AC capacitive ignition system capable of independently controlling both spark current and duration is considered in the experiments. The spark plugs used in the experiments are of dual nickel standard J-gap design of different electrode gaps and center electrode diameters. The study has utilized the central composite design of experiments methodology to study multiple parameter interactions. The hypothesis from test results indicate that an increase in both gas pressure and spark plug electrode gap require a high spark current to sufficiently deposit energy to the gas at constant electrode diameter. On the contrary, an increase in electrode diameter requires high

Saha, Anupam, Tunestal, Per, Aengeby, Jakob, Andersson, Oivind

Characterization of low-density gas spray structure and vorticity using PIV technique

2025-24-0067To be published on 09/07/2025

In view of the increasing interest towards hydrogen, such as its utilization for road transport sector decarbonisation, in the current study helium has been employed as substitute to characterize the spray structure through the use of the particle image velocimetry (PIV) technique. The experimental test campaign implied the use of a gaseous injector capable of delivering the substitute fuel up to 50 bar in a constant volume spray – chamber, which pressure has been varied in order to scrutinize the influence of environment density on jet structure. Two configurations were employed: one consisting of a free path of distribution of the spray, the second including a metal plate positioned perpendicularly 50 mm from the injector tip, thus making it possible to observe the spray – wall interactions under several conditions. The illumination was provided by a dual cavity Nd:YAG laser and a 4-megapixel camera used for image capture. The influence of pressure ratio (PR) was evaluated over a

Cecere, Giovanni, Andersson, Mats, Merola, Simona, Irimescu, Adrian

Enabling near-zero emissions and superior efficiency in large-bore, medium-speed engines with a hydrogen-argon power cycle

2025-24-0001To be published on 09/07/2025

Combustion engines operating on a hydrogen-argon power cycle (H-APC) offer potential for superior thermal efficiency with true zero exhaust emissions. The high specific heat ratio of argon allows extrapolation of the theoretical efficiency of the Otto cycle to almost 90%. However, this potential is significantly constrained by challenges in combustion control, excessive thermal loading, and system integration, particularly regarding argon recovery. This study investigates these trade-offs, within the context of real-world engine-based peaking power plants. An experimentally validated 1D-simulation model of a prototype Wärtsilä 20 DF engine serves as reference for analysis of a retrofit incorporating a closed-loop argon cycle, with dedicated H₂ and O2 injectors, a water condenser and water separator. Engine performance is evaluated at reference operating point of 75% load, considering pre-ignition, peak pressure and exhaust temperature constraints, condenser limitations, and impurity

Ahammed, Sajid, Ahmad, Zeeshan, Mahmoudzadeh Andwari, Amin, Kakoee, Alireza, Hyvonen, Jari, Mikulski, Maciej

Influence of the SCR reactivity on passive soot oxidation for vanadium-coated and uncoated (S)DPF

2025-24-0086To be published on 09/07/2025

In modern diesel exhaust aftertreatment systems (EATS), combining a catalytic coating for selective NOx reduction (SCR) with a diesel particulate filter (DPF) enables simultaneous particulate filtration and NOx reduction. In such systems, soot regeneration is primarily influenced by the NO2 supply in the exhaust gas, particularly at low exhaust temperatures (250-400 °C). Several investigations found that in SCR-coated filters with urea-water solution (UWS) dosing upstream, particle oxidation is partially inhibited by NH3. However, at higher temperatures (>400 °C), this effect seems to be reduced. In this study, numerical modelling approaches based on engine test bench results are utilised to examine the impact of SCR reactivity on passive soot oxidation for a highly porous vanadium-coated SDPF. To identify the interaction mechanism between the SCR reaction and soot oxidation, further investigations were conducted using a filter with a washcoat without SCR-active component. The

Prchal, Niklas, Wegmann, Andreas, Müller, Werner, Günthner, Michael

Thermal Stress Reduction in Diesel Engine Pistons Using Semitransparent Ceramic Coatings: A 3D Numerical Study with OpenFOAM

2025-24-0003To be published on 09/07/2025

This research focuses on the thermal analysis of internal combustion engine pistons, evaluating the effects of high-temperature exposure during operation. A three-dimensional numerical study is conducted using OpenFOAM, modifying the software’s governing equations to analyze temperature distribution in different piston geometries. The study aims to assess the spatial temperature variation within the entire volume of the piston, providing a detailed understanding of heat transfer mechanisms. A multilayer approach is implemented, considering various configurations of ceramic coatings with distinct thermal and optical properties. The investigation incorporates an internal heat source model, where the heat absorption characteristics of the coating material influence the thermal behavior of the system. By evaluating aluminum- and titanium-based ceramic coatings, the study examines how semitransparency and heat radiation absorbance affect heat accumulation and transfer. The results highlight

Gutierrez, Marcos, Taco, Diana, Bösenhofer, Markus

Spray Dynamics and Collapsing Process of Methanol and Gasoline in a Lateral-cylinder-mounted DI Injector

2025-24-0063To be published on 09/07/2025

The morphology and collapsing behavior of fuel sprays play a critical role in determining atomization and vaporization characteristics, directly influencing combustion efficiency and emission formation in direct injection systems. In this study, spray dynamics and collapsing processes of methanol and gasoline fuels were examined using a lateral-cylinder-mounted direct injection (DI) injector in a constant volume combustion chamber (CVCC). A tomographic imaging technique was applied to analyze the spatial and temporal characteristics of fuel sprays. Extinction imaging was performed to capture the distribution of droplets within the spray, and the liquid volume fraction (LVF) was quantified based on the Beer-Lambert law. By acquiring extinction images from multiple viewing angles, 3D tomographic reconstructions of the spray morphology were achieved, providing detailed insights into the structural evolution of the sprays during injection. The high latent heat of vaporization of methanol

Kim, Hyunsoo, Lee, Seungwon, Bae, Sumin, Hwang, Joonsik, Bae, Choongsik

Numerical analysis of in-nozzle flow of methanol injectors for large marine two-stroke engines

2025-24-0069To be published on 09/07/2025

A statistical method for analyzing momentum deflection angles of fuel injectors based on Computational Fluid Dynamics (CFD) simulation of the internal nozzle flow is proposed. This method is especially relevant for large marine two stroke engines where the spray is often deflected due to an eccentric and asymmetric design of the internal injector geometry. Unsteady Reynolds-Averaged Navier-Stokes (URANS) CFD simulations are employed to analyze the internal flow of different cavitating injectors which have four and five nozzle holes, respectively, for a 50 cm bore and a 95 cm bore dual-fuel engine operating on methanol. The in-nozzle flow dynamics vary from one to another significantly. The use of the statistical analysis on the distribution of deflection angles at the fuel nozzle hole exit further assists at explaining differences in measured surface temperatures of the exhaust valve bottom and piston bowl. The corrected spray angles obtained from these in-nozzle simulations also serve

Quist, Nicolai, Matlok, Simon, Pang, Kar Mun, Norman, Thomas, Mayer, Stefan, Walther, Jens

S.I.S.T.E.R.: an integrated approach to non-exhaust emissions

2025-24-0091To be published on 09/07/2025

As electric mobility spreads and evolves, non-exhaust Particulate Matter sources are gaining more attention for total vehicular emissions. A holistic approach for studying the involved phenomena is necessary to identify the parameters that have the greatest impact on this portion of emissions. To achieve this, it is needed to develop a new platform capable of both creating testing methodologies for future regulations and enabling the parallel development of advanced tires and brakes that meet these standards, by correlating vehicle dynamics, driving style, tire and brake characteristics, and the resulting emissions. Here the authors present the Sustainable Integrated System for Total non-Exhaust Reduction (S.I.S.T.E.R.) project, funded by the Italian Centro Nazionale per la Mobilità Sostenibile (MOST), that aims to develop an integrated approach to study tire/brake-related emissions from the initial stages of compound development to outdoor vehicle tests, allowing actions to be taken

Genovese, Andrea, De Robbio, Roberta, Lenzi, Emanuele, Caiazza, Antonio, Lippiello, Felice, Costagliola, Maria Antonietta, Marchitto, Luca, Serra, Antonio, Arimondi, Marco, Bardini, Perla

Numerical Investigation of Lean Neat Ammonia Combustion in a Heavy-Duty Diesel Engine Converted to Spark Ignition

2025-24-0032To be published on 09/07/2025

Ammonia (NH3) use as fuel poses technical challenges such as increased nitrogen-based and unburned NH3 emissions. This study used a 0D model coupled with detailed NH3 kinetics to evaluate the effect of equivalence ratio (ϕ) from 0.7 to 1.0 in a heavy-duty compression ignition engine converted to spark ignition operation. The goal was to evaluate how ϕ affected NOx and N2O formation and/or destruction at constant fuel energy per cycle, engine speed, and CA50. Simulated NOx emissions (i.e., NO + NO2) followed a trend similar to the one typically observed for hydrocarbon fuels in a SI engine, but that was different from the experiment. In addition, it underpredicted NOx emissions for ϕ = 0.7 by 79% and overpredicted NOx emissions for ϕ = 1 by 576%. The simulation showed that thermal NO production was more than 80% from the total NO production, but the effect of ϕ on this percentage was negligible. Then, predicted N2O emissions had an opposite trend and were three orders of magnitude lower

Saenz Prado, Stefany, Alvarez, Luis F., Trujillo Grisales, Juan M., Akkerman, Vyacheslav, Dumitrescu, Cosmin E.

An optimized particle collection system for PM10 and PM2.5 tyre wear emission factors under real-world conditions

2025-24-0093To be published on 09/07/2025

The growing demand for greener transport along with progress in vehicle electrification has led to an increased focus on accurate Emission Factors (EFs) for non-exhaust sources like tyres. Tyre wear arises through mechanical and thermal processes, generating Tyre Road Wear Particles (TRWP) composed of rubber polymers, fillers, and road particles. This research aims to establish precise tyre airborne EFs for real-world conditions, emphasizing in an efficient collection system to generate accurate PM10 and PM2.5 EFs from passenger car tyres. Particle generation replicates typical driving on asphalt road for a wide selection of tyres (different manufacturers, price ranges, fuel economy rating). Factors such as tyre load, speed and vehicle acceleration are also considered to cover various driving characteristics. The collection phase focuses on separating tyre wear particles from potential contaminants, such as brake particles and other road particles, while maintaining high capture

Kontses, Dimitrios, Dimaratos, Athanasios, Kaimakamis, Thomas, Vizvizis, George, Ouzounis, Rafail, Koutsokeras, Odysseas, Samaras, Zissis

Analysis of DC Current and Voltage Ripples of Electrical Drivetrains for HV Electrical System Emulation

2025-24-0135To be published on 09/07/2025

State-of-the-art testing of traction inverters is conducted using PHIL-based testbeds. These systems, which include a battery emulator and an E-Motor Emulator (EME), offer significant advantages over dynamometer testbeds in terms of test duration, reproducibility, parameterization and protection of the unit under test. In these advanced systems, the physical modeling of the AC side (e-motor) is highly detailed, accounting for factors such as iron saturation effects, current harmonics, and loss models. However, the DC side models are limited to a constant voltage and an internal resistance model, neglecting other components like additional traction inverters or DC/DC converters connected to the HV electrical system and their impact on voltage and current ripples – high-frequency oscillations in the current that can arise from power electronic systems. This research project aims to address this gap by developing an HV electrical system emulator that considers these influences. This

Merath, Stefan, Winzer PhD, Patrick, Reick, Benedikt

Experimental Simulation of a Real Mission for Identifying a Telematics-Based Diagnostic Model in Connected Light Commercial Vehicles

2025-24-0124To be published on 09/07/2025

Remote monitoring of commercial vehicles is taking an increasingly central position in automotive companies, driven by the growth of the on-road freight transportation sector. Specifically, telematics devices are increasingly gaining importance in monitoring powertrain operability, performance, reliability, sustainability, and maintainability. These systems enable real-time data collection and analysis, offering valuable support in resolving issues that may occur on the road. Moreover, the fault codes, called Diagnostic Trouble Codes (DTCs), that arise during actual road driving constitute fundamental information when combined with several engine parameters updated every second. This integration provides a more accurate assessment of vehicle conditions, allowing proactive maintenance strategies. The principal goal is to deliver an even faster response for resolving sudden issues, thus minimizing vehicle downtime. High-resolution data transmission and failure event information

D'Agostino, Valerio, Cardone, Massimo, Mancaruso, Ezio, Rossetti, Salvatore, Marialto, Renato

Parametric Analysis of Liquid Ammonia Direct Injection for Optimal Ammonia-Hydrogen Combustion in Spark-Ignition Engines

2025-24-0072To be published on 09/07/2025

As the global effort to reduce carbon emissions intensifies, ammonia has emerged as a promising fuel alternative due to its carbon-free molecular composition. This study explores the potential of direct liquid ammonia injection combined with port fuel hydrogen injection technology in a spark ignition engine, leveraging Computational Fluid Dynamics (CFD) simulations informed by experimental data and literature. The methodology involves reproducing and validating an evaporation model sourced from the literature. Once validated, the fraction of injected liquid ammonia actively participating in combustion was quantified, an essential step in refining the engine combustion simulation. The engine model was divided into two key simulations: (i) a Volume of Fluid (VoF) simulation of the injector to characterize ammonia behavior at the nozzle outlet, and (ii) an engine simulation utilizing a Lagrangian spray configuration, based on the VoF results and the validated evaporation model. The

Silvestrini, Sandro, Kinkhabwala, Brijesh, Kubach, Heiko, Koch, Thomas, Seba, Bouzid

Optical diagnostic analysis of methane combustion performance and emissions while incorporating ammonia and multiple flames in a spark-ignition engine

2025-24-0023To be published on 09/07/2025

The current state of internal combustion engine technology necessitates the use of cleaner fuels with lower carbon content in order to mitigate CO2 release into the atmosphere. Ammonia and methane show potential as alternatives to traditional hydrocarbon fuels due to their ability to reduce carbon emissions. This study investigated the use of different energy fractions of ammonia in a methane mixture to reduce carbon-based emissions. However, ammonia, being a less reactive fuel with a lower flame speed than methane, may negatively impact engine performance. To address this, the study employed a multiple flame generation approach to accelerate the combustion rate. The experiment was carried out on a single-cylinder four-stroke optical research engine. To initiate multiple flame fronts, a customized metal liner with four equi-spaced spark plugs was utilized. To compare the results with conventional spark-ignition conditions, one spark plug was placed at the center of the cylinder head

Uddeen, Kalim, Tang, Qinglong, Shi, Hao, Turner, James

Integrated CFD-Experimental Methodology for Hydrogen-Fuelled Small Loop Scavenged Two-Stroke Engines

2025-24-0014To be published on 09/07/2025

This paper presents an integrated methodology for the analysis of hydrogen-fuelled two-stroke engines, combining experimental data, 1D CFD simulations, and 3D CFD combustion calculations. The proposed approach aims to enhance the understanding of scavenging, injection, and combustion processes in a 50 cc loop-scavenged engine with low-pressure direct hydrogen injection (LPDI), experimentally studied on a test bench. The performance of the hydrogen-fuelled engine was slightly lower compared to gasoline operation, achieving a maximum power output of 3.1 kW compared to 3.6 kW with gasoline, using a slightly lean air-fuel ratio (lambda = 1.3). The maximum engine speed for stable combustion without knocking was achieved at wide-open throttle (WOT) at 7000 RPM. The developed 1D CFD model, based on the layout at the test bench, was calibrated using average experimental data and specific full-load operating points. 3D CFD simulations were performed for two full-load operating points, focusing

Caprioli, Stefano, Ferretti, Luca, Scrignoli, Francesco, Fiaschi, Matteo, D'Elia, Matteo, Oswald, Roland, Schoegl, Oliver, Nambully, Suresh Kumar, Rothbauer, Rainer, Mattarelli, Enrico, Kirchberger, Roland, Rinaldini, Carlo

Analysis of Momentum Flux Distribution in Jets Produced by a Hydrogen Direct Injection System

2025-24-0065To be published on 09/07/2025

The adoption of hydrogen as carbon-free fuel for internal combustion engines in both transport and off-road applications could offer a significant contribution towards carbon neutrality. In the technical pathway to the conversion of conventional engines operating with liquid fuels to hydrogen, a key role is played by the injection systems. In particular for direct-injected combustion systems, the achievement of an adequate capability to control the gas jets development and the following mixing with air in the combustion chamber is mandatory in order to govern the heat release rate, so to obtain high efficiency levels while limiting the knock tendency and NOx formation. In order to achieve this complex task, the development of effective diagnostic methodologies for a satisfactory characterization of high-pressure gas jets is required in order to obtain a proper matching with the combustion chamber design and air charge flow structure. In the present paper, the jet produced by a

Postrioti, Lucio, Fontanesi, Stefano, Martino, Manuel, Maka, Cristian, Breda, Sebastiano, Falcinelli, Francesco, Ricci lng, Andrea

Toward sustainable Heavy-Duty transport: evaluating charge dilution and Advanced Corona Ignition System effects on SI natural gas engine efficiency and combustion characteristics

2025-24-0024To be published on 09/07/2025

Reducing greenhouse gas (GHG) emissions in the transportation sector is a significant challenge. A multi-technology approach is the most practical and sustainable solution for minimizing the environmental impact of road transport. Alternative gaseous fuels derivable from bio sources have the potential to significantly cut CO2eq emissions from a Well-to-Wheel perspective, and the development of technologies that allow to improve the efficiency of natural gas-powered Heavy Duty (HD) Spark Ignition (SI) engines is of strategic importance. In such applications, charge dilution strategies might have the potential to increase engine efficiency at a relatively low implementation cost. Diluting the in-cylinder charge can reduce fuel consumption by decreasing wall and pumping losses, and increasing the Heat Capacity Ratio. The coupling with innovative technologies aimed at enhancing ignition energy, influencing combustion development, could be a promising scientific path for achieving more

Di Domenico, Davide, Napolitano, Pierpaolo, Papi, Stefano, Ricci, Federico, Golini, Stefano, Rapetto, Nicola, Giordana, Sergio, Beatrice, CARLO

Experimental Analysis of Enhanced Scavenging Efficiency in Hydrogen-Powered Internal Combustion Engines for Heavy-Duty Applications.

2025-24-0056To be published on 09/07/2025

The purpose of this work is to highlight the benefits of increased scavenging efficiency for premixed, lean-burn, spark-ignited heavy-duty engines fueled by hydrogen. Scavenging efficiency measures the effectiveness of replacing exhaust gases with fresh air or an air-fuel mixture within the cylinder of an internal combustion engine. Enhanced scavenging efficiency reduces residual gas content and increases the proportion of fresh air, resulting in a cooler local mixture temperature. Additionally, it improves heat dissipation within the combustion chamber, cooling potential hotspots and allowing for earlier injections with fewer restrictions due to combustion anomalies, particularly preignitions. To increase scavenging efficiency in a 4-stroke internal combustion engine, valve timing adjustments were made by introducing a camshaft with greater overlap of the exhaust valve closing and the inlet valve opening sequences. Additionally, a high-efficiency turbocharger was used to reduce

Schuette, Christoph, Borg, Jonathan, Giordana, Sergio, Rapetto, Nicola

Towards Effective SCR System Optimization: A 3D-CFD and Experimental Study Enabling Faster Deposit Formation Risk Assessment

2025-24-0087To be published on 09/07/2025

Selective Catalytic Reduction (SCR) is a key technology for reducing nitrogen oxides (NOx) emissions in diesel engines. In this process, a urea-water solution (UWS) is injected upstream of the catalyst to generate ammonia, which reacts with NOx to form nitrogen. However, liquid urea can adhere to system walls, undergoing secondary reactions that lead to the formation of solid deposits. These deposits must be minimized to ensure the long-term durability and efficiency of the system. Computer-Aided Engineering (CAE) simulations play a crucial role in optimizing SCR performance during the design phase. However, accurately predicting deposit formation requires detailed chemical modelling, which is computationally expensive and introduces uncertainties related to reaction mechanisms definition. To address this challenge, simplified CAE approaches are needed to assess deposit formation risks while maintaining computational efficiency. This study presents an improved Deposit Risk Index (DRI

Bianco, Andrea, Prestifilippo, Mattia, Robino, Cristina, Petrafesa, Giovanni, Postrioti, Lucio, Buitoni, Giacomo

Comparing different electrical architectures for a parallel PEMFC-battery hybrid electric lightweight vehicle

2025-24-0110To be published on 09/07/2025

In the field of hybrid powertrains for sustainable mobility, fuel cells are a promising solution to improve the performance of battery electric vehicles by implementing PEMFCs as REx. The selection of proper power electronics, such as converters, is fundamental to guarantee tight control and electrical stability. In this paper, a comparison between different electrical architectures of an electric hybrid PEMFC/battery vehicle is proposed: a light battery electric quadricycle (EU L6e) with four in-wheel motors is hybridized with a 3 kW open-cathode PEMFC as REx in parallel layout. The battery accounts for a bi-directional DC/DC converter to stabilize the voltage at 48V, needed by EMGs. A passive architecture is firstly considered, with the PEMFC stack connected to the battery poles; the second architecture is a semi-active one, with the PEMFC connected after the battery DC/DC converter; the last considered layout is active, with a unidirectional DC/DC converter between PEMFC and

Sicilia, Massimo, Cervone, Davide, Polverino, Pierpaolo, Pianese, Cesare

Development of a compact hydrogen engine for commercial applications

2025-24-0060To be published on 09/07/2025

As the individual and commercial vehicle industries seek sustainable alternatives to conventional internal combustion engines, hydrogen-fueled rotary engines are emerging as a promising solution for several applications. This paper presents an innovative approach for the development of a hydrogen rotary engine that is integrated within a hybrid system. By exploiting the unique characteristics of rotary engines, such as compact size and high power-to-weight ratio, the electric machine, the battery and the rotary engine can be accommodated in the installation space of a conventional ICE with comparable power, despite the reduced power density of hydrogen as a fuel in internal combustion engines. In this way, the proposed system aims to avoid CO2 emissions and improve the overall performance of the powertrain. As a first step, the hydrogen engine is naturally aspirated and equipped with direct injection. To develop a suitable calibration for the engine’s application, the influence of

Endres, Jonas, Beidl, Christian, Hofmann, Silas

Numerical Investigation on an Injection Strategy Optimization for Dual Fuel Marine Engine Fuelled by Ammonia

2025-24-0013To be published on 09/07/2025

In the context of greenhouse gas reduction (GHG) the most viable short-term solution in the maritime sector is the use of renewable carbon-free fuels. Among these, ammonia represents a possible alternative in compression ignition (CI) engines operating in dual fuel (DF) mode. Although, such fuel features low chemical reactivity, especially in lean mixtures, resulting in poor combustion efficiency, exhaust ammonia slip and low engine performance, DF combustion can be an interesting strategy to overcome such combustion limitations. In this work a wide examination of diesel injection strategies is numerically presented, while ammonia acts as the primary fuel with energy shares around 80%. Since the original marine engine, fuelled with natural gas (NG), presents a single diesel injection, firstly, a pilot injection is added and different diesel mass distributions between pilot and main are investigated, by varying the injection rate shape and the pilot start of injection (SOI

Cameretti, Maria Cristina, De Robbio, Roberta, Palomba, Marco

Simulation of Swirl and Discharge Coefficient Trade-off for Diesel Engine Intake Ports

2025-24-0007To be published on 09/07/2025

In Diesel engines, charge motion usually consists of swirl and squish flow patterns. Traditionally, swirl generation is controlled through the design of the intake ports, presenting a trade-off between swirl and mass flow rate. An alternative approach to generate swirl is to use vortex-generating jets in the intake port. As a comparative basis for this approach a Pareto front was established between swirl and mass flow rate based solely on geometric variations. A new fully parametric geometry was deployed, with two intake ports per cylinder adhering to some constraints. Stationary flow-bench test setup was modeled, where a blower draws air through the intake ports at a constant pressure difference. The Pareto front was generated using semi-randomly selected geometries in combination with automated unsteady RANS (URANS) simulations, while scale adaptive simulations (SAS) were also employed on select geometries. These turbulence modeling approaches were explored using the OpenFOAM

Kahraman, Ali Berk, Ritter, Johann, Eilts, Peter, Scholz, Peter

Numerical Analysis of the Combustion Process in a Hydrogen-Fueled Pre-Chamber Combustion Engine

2025-24-0012To be published on 09/07/2025

Direct injection hydrogen internal combustion engine (ICE) has emerged as a promising alternative fuel due to its potential to enable clean and sustainable energy systems. However, the rapid injection of low-density hydrogen leads to strong mixture stratification and strong flame-turbulence-wall interactions. This challenge is exacerbated in the high-performance engine under study operating at a high engine load (indicated mean effective pressure of about 20 bar) and speed (7500 revolutions per minute). Furthermore, to target high efficiencies, restrict abnormal combustion behaviors, and inhibit oxides of nitrogen emissions, a lean-burn combustion strategy with a global equivalence ratio of 0.4 was applied, where diffusive-thermal (DT) instability effects further complicate the flame characteristics. Additionally, to promote engine performance, the pre-chamber (PC) combustion concept was applied, further complicating the turbulent flame dynamics. To address the modeling challenges and

Mortellaro, Fabio Santi, Menaca, Rafael, Liu, Xinlei, Im, Hong G., Tonelli, Roberto, Medda, Massimo

Thermal Characterization of a High-Power Lithium-Ion Pouch Cell and Surface Temperature Prediction for Motorsport Applications

2025-24-0142To be published on 09/07/2025

Accurate cell thermal characterisation is vital for battery modelling and thermal management, especially in motorsport, where minor temperature estimation errors can have severe consequences. Conventional methods for determining key thermal parameters, such as the specific heat capacity, often require costly calorimeters or destructive testing. Recent studies propose an alternative approach using a 1D lumped thermal network to solve the thermal balance of a heat-generating cell. However, these studies often overlook critical aspects of the heat generation equation, particularly the entropic term, which is essential for capturing nonlinear thermal behaviour, especially under dynamic cycling conditions. This study presents a cost-effective approach for rapid cell thermal characterisation and accurate surface temperature prediction. A pouch LCO cell was first tested to determine the entropic coefficient, followed by experiments under two convective conditions to evaluate its specific heat

Sciortino, Davide Domenico, Schommer, Adriano, Costa, Andre

Premixed Hydrogen-Methane Combustion Modelling in a Pre-Chamber RCEM with Flamelet-Based and Detailed-Chemistry Approaches

2025-24-0046To be published on 09/07/2025

In the fight against climate change, one of the key pathways to decarbonizing the transport sector is the use of alternative fuels in internal combustion engines. Hydrogen emerges as a promising solution for transforming internal combustion engines into a greener alternative, paving the way for a fuel-flexible era and enabling a rapid reduction in tailpipe carbon emissions. Coherent with this vision, this numerical study investigates different hydrogen/methane mixtures to evaluate the performance of various combustion models based on different modelling approaches. On one hand, a flamelet-based model (ECFM) is presented, demonstrating its ability to fit experimental data through a calibration process that manages turbulence-chemistry interactions by adjusting model parameters. On the other hand, a detailed chemistry solver (SAGE), which employs a kinetics mechanism and does not require calibration, is also analysed in this paper and results are compared against the one coming from the

Sola, Riccardo, Baratta, Mirko, Misul, Daniela, D'Elia, Matteo, Ferretti, Luca, Venkataramanan, Jyothish kumar

Battery datasets for neural network-based State-of-Health estimators: a review and implementative workflow

2025-24-0139To be published on 09/07/2025

Correct management of the battery systems for electric vehicles, at pack, module and cell level, has critical importance to ensure safe and efficient operation. Proper control at cell level, requires estimation of battery statuses, such as the State-of-Charge and the State-of-Health, as they cannot directly measured during vehicle operation. With the increasing advances in sensor availability, edge computing and the development of big data, data-driven approaches have gained increasing interest. In particular, due to their great flexibility and potential in mapping non-linear relations within data, application of machine learning (ML) and neural networks (NNs) in SoH estimation have been thoroughly investigated. The numerous studies available in literature leveraged extracted different features from data to train NNs, or directly used measurements signal as input. Additionally, many studies available in literature are based on a limited number of publicly available datasets, which

Chianese, Giovanni, Capasso, Clemente, Veneri, Ottorino

Overview of Current Developments of Pre-chamber Spark Plugs for Passenger Car Applications

2025-24-0152To be published on 09/07/2025

The internal combustion engine (ICE) will remain the key technology in the transport sector over the short and medium term. While alternative technologies such as battery electric vehicles face charging and storage limitations, there is still potential for improvements in fuel economy and reduced emissions from ICEs. A promising technology to further improve the efficiency of the spark ignition engine is the passive pre-chamber spark plug. The main advantages of pre-chamber-initiated combustion are knocking mitigation, increase of the in-cylinder turbulence, and combustion, which is faster and more stable in comparison to the conventional (J-gap) spark plug. Moreover, the higher ignition energy compared to J-gap spark plugs enables the operation of load points with higher intake pressure, similar exhaust recirculation rates, and leaner combustion. These advantages are mainly due to volumetric ignition by hot and reactive jets. The pre-chamber plug has two main disadvantages, which are

Korkmaz, Metin, Juressen, Sven Eric, Rößmann, Dominik

Evaluating safety behavior of Li-ion batteries regarding negative electrode composition

2025-24-0149To be published on 09/07/2025

Li-ion battery (LiB) overall performance depends highly in the electrode materials. The composition of the negative and positive electrodes will have an impact on crucial aspects of the Li-ion cell: energy density, ageing behavior and thermal stability. Consequently, material selection in electrodes composition is one of the key aspects in battery research. Therefore, the study of a Li-ion cell, disregarding the axe of study, must consider this aspect. Negative electrodes have regularly been composed of graphite and some additives to increase conductivity or mechanical properties. One advance direction in LiBs field is the inclusion of silicium to form a blend negative electrode Si-Gr. This article introduces the evaluation of the negative electrode composition (standard Gr vs Si-Gr) in the performance of two recent models of Li-ion 21700 batteries of the same manufacturer in two main aspects: electric and safety behavior. Recently, the addition of SiOx to the standard graphite

Cruz Rodriguez, Jesus Armando, Lecompte, Matthieu, Redondo-Iglesias, Eduardo, Pelissier Sr, Serge, abada PhD, Sara

A comprehensive electro-thermal and fluid-dynamic model for liquid-cooled lithium-ion cells: development and experimental validation

2025-24-0145To be published on 09/07/2025

The temperature evolution of lithium-ion cell under operation has a significant impact on their performance, efficiency, and ageing. Modeling the thermal status of lithium-ion cells is crucial to predict and prevent undesired working conditions or even failures. In this context, this paper presents a mathematical model to predict the transient temperature distributions of a lithium-ion metal polymer battery (LMP) cooled by forced convection via a specially designed channel plate for liquid cooling. For the battery modeling, the Newman’s pseudo-2D approach was used to perform a computational fluid dynamics (CFD) analysis. It assumes that the porous electrode is made of equally sized, isotropic, homogeneous spherical particles, which results in smooth, uniform intercalation/de-intercalation of lithium inside the electrode. Also, the channel plate geometry and the cooling liquid fluid-dynamic behavior were simulated with a commercial code based on the finite volume method. The model has

Ferrari, Cristian, Magri, Luca, Sequino, Luigi

Neural-Based Real-Time Driving Suggestions System for Components Preservation in Battery Electric Vehicles Using Model-Based Datasets

2025-24-0115To be published on 09/07/2025

Nowadays, Battery Electric Vehicles (BEVs) are considered an attractive solution to support the transition towards more sustainable transportation systems. Although their well-known advantages in terms of overall propulsion efficiency and exhaust emissions, the diffusion of BEVs on the market is still reduced by some technical bottlenecks. Among those, the uncertainty about the expected durability of the vehicle on-board battery packs plays a key role in affecting customer choice. In this context, this paper proposes the use of model-based datasets for training a driving support system based on machine learning techniques to be installed on board. The objective of this system is to acquire vehicle, environmental, and traffic information from sensors’ networks and provide real-time smart suggestions to the driver to preserve the remaining useful life of vehicle components, with particular reference to the battery pack and brakes. For the generation of the training dataset, first, a set

Bernardi, Mario Luca, Capasso, Clemente, Iannucci, Luigi, Sequino, Luigi

Development of a cloud based operating strategy for an electrified trailer system

2025-24-0117To be published on 09/07/2025

The need for greenhouse gas emission reductions leads to decreasing emission limits in road traffic. The development of efficient powertrains and the use of renewable energy sources are crucial in order to meet these targets. Electrification is one of the key technologies that can help to achieve higher efficiency and lower emissions. Besides the passenger car segment, electrification has started to play a more important role in heavy-duty applications as well. One technology that has been discussed in the last years is the electrification of heavy-duty semi-trailers. In the joint research project "evTrailer2" funded by the German Federal Ministry for Economic Affairs and Climate Action, the potential of different technologies for electrified semi-trailer systems in long-haul applications is evaluated. The overall project goal is the development of high efficiency technologies to help reduce the fuel consumption and therefore the greenhouse gas impact of large semi-trailer trucks. The

Knaup, Lars, Beidl, Christian

Multilevel control strategy design and optimization for fuel cell hybrid heavy-duty vehicles

2025-24-0107To be published on 09/07/2025

The heavy-duty transportation sector is a major contributor to greenhouse gas emissions, highlighting the urgent need for zero-emission solutions. This research aims to develop a multilevel control architecture that optimizes fuel economy and minimizes emissions in fuel cell hybrid heavy-duty vehicles (FCH2DV), equipped with proton exchange membrane fuel cell and battery pack as the main power sources. The detailed fuel cell system model incorporates mass and thermal dynamics, including air supply, hydrogen flow, water management and their effects on reaction kinetics, membrane conductivity, water balance, performance and durability. The low-level control strategy is designed using a physics-based approach that accounts for critical constraints, including temperature, relative humidity and differential pressure between the cathode and anode. By identifying the optimal setpoints for key control variables, this methodology enables the development of accurate control maps for actuator

Bove, Giovanni, Aliberti, Paolo, Simone, Christian, Sorrentino, Marco, Pianese, Cesare

Τesting and modeling of a passive SCR system for hydrogen engines

2025-24-0082To be published on 09/07/2025

Heavy-duty vehicles powered by hydrogen internal combustion engines (H2 ICEs) present a compelling solution for sustainable transportation.. When optimized for ultra-lean operation, H2 ICEs are capable of meeting the most stringent contemporary legislative emission standards. However, achieving optimal drivability necessitates occasional to an enriched operating mode, thereby presenting significant challenges in maintaining ultra-low emissions. In this context, the implementation of advanced exhaust after-treatment technologies becomes essential to ensure near-zero tailpipe emissions with minimal impact on fuel efficiency and drivability. This paper investigates the potential of a passive Selective Catalytic Reduction (SCR) exhaust configuration for a heavy-duty hydrogen (HD H₂) engine, employing testing and modeling of a Lean NOx Trap, utilized as an ammonia (NH₃) generator, in conjunction with a downstream Selective Catalytic Reduction system. We underscore the complexities

Zafeiridis, Menelaos, Alexiadou, Panagiota, Koltsakis, Grigorios

Analysis of combustion characteristics and performance of a multi-cylinder Dual-fuel HCCI engine.

2025-24-0042To be published on 09/07/2025

Despite significant advancements in internal combustion engine efficiency, fossil fuels still hinder progress toward sustainable energy. Syngas, a gasification byproduct of hydrogen and carbon monoxide, is a promising transitional fuel due to its compatibility with existing combustion technologies, improved efficiency, and lower emissions. It is well-suited for HCCI engines, known for high thermal efficiency and reduced NOₓ and particulate emissions. However, Syngas combustion requires elevated intake temperatures or admission pressures to ensure optimal thermodynamic conditions. To overcome this, a small quantity of diesel enhances ignition stability and extends the engine’s operational range in dual-fuel combustion. While most previous experimental studies have focused on syngas-diesel dual-fuel operation in single-cylinder setups, this research expands the analysis to a multi-cylinder engine. It accounts for cylinder-to-cylinder variations, chemical interactions, and thermal

EL YOUNSI, Laila, Nelson-Gruel, Dominique

Innovative Full-GaN Inverter Development for 800V/100kW Automotive Applications

2025-24-0133To be published on 09/07/2025

This abstract presents the development of an automotive traction inverter utilizing cutting-edge full-GaN technology, incorporating components from CGD for high-performance 800V applications. The inverter employs a three-level topology, which is a significant advancement over the conventional two-level designs predominantly used in the current state of the art. This design aims to enhance efficiency, reduce power losses, and improve thermal management compared to traditional IGBT and SiC-based inverters. In this article is detailed a scientific approach which focused on developing a mock-up to validate the power scaling of GaN components, to the complete design of a full-scale prototype representing an automotive traction inverter. Comparative analysis in the article demonstrates that the GaN-based three-level inverter not only surpasses traditional two-level IGBT and SiC inverters in terms of efficiency and thermal performance but also shows promising potential in improving signals

BATTISTON, Alexandre, Aghaei Hashjin, Saeid, FINDLAY, John, Haje Obeid, Najla, Siad, Ines

Vehicle Under-Hood Thermal Management: Development of a Reduced-Order Model for Accurate and Computationally Efficient Temperature Distribution Simulations

2025-24-0118To be published on 09/07/2025

Electrified vehicle energy management plays a crucial role in the context of the European Green Deal by facilitating the transition toward sustainable mobility. The development of predictive and robust simulation tools is essential to implement and test different energy management strategies. This study aligns with this objective by presenting the development of an under-hood flows model designed for integration into a 1D vehicle simulator, which is used to perform vehicle simulations about longitudinal performances, energy consumption and range. Vehicle under-hood thermal management is inherently complex due to the interplay of internal flow dynamics and multiple heat transfer mechanisms. A purely 1D modeling approach lacks the spatial resolution required to capture detailed flow field characteristics, while a fully 3D CFD model is computationally prohibitive for scenarios requiring efficient simulations. To address this trade-off, a reduced-order model (ROM) approach is proposed. The

Miccio, Stefano, Grattarola, Federico, Baratta, Mirko, Giraudo, Gabriele, Frezza, Davide, Bartolucci, Lorenzo

Development of an Euro VII Compliant Diesel Combustion System for Light Commercial Vehicles

2025-24-0035To be published on 09/07/2025

Recent European regulations introduced in the transportation sector have increased stringency on tailpipe CO2 and regulated emissions, starting 2025. The development of advanced engine technologies and the utilization of alternative fuels for internal combustion engines plays a key role in the short- to mid- term in complying with such regulations and supporting sustainable transition. In this study, the focus has been to develop an advanced Diesel combustion system for light commercial vehicles application in compliance with the latest Euro VII regulations and with the primary aim to improve fuel economy. The adopted methodology considered a coupled 1D-3D CFD virtual development and optimization of the entire combustion system encompassing bowl shapes, injector nozzles, and intake port specifications. Two advanced combustion system ‘recipes’ have been identified and then experimentally investigated to fine-tune the nozzle specifications, injection strategies and charge motion by means

Belgiorno, Giacomo, Malagrinò, Gianfranco, Pezza, Vincenzo, Spedicato, Tonio, Storsillo, Vito, Gallone, Alessandro, Alletto, Massimiliano, Pesce, Francesco, Vassallo, Alberto, Colombo, Giovanni, Formica, Angelo, Lerda, Francesco, Mirzaeian, Mohsen, Vitiello, Michele

Water injection as an enabling technology for stoichiometric high performance normally aspirated engines

2025-24-0027To be published on 09/07/2025

The mainstream automotive market is rapidly transitioning to electrified and fully electric powertrains. Where gasoline engines are still employed, they are frequently turbocharged units with relatively low maximum engine speed and modest power density. The hypercar class, in contrast, has recently seen somewhat of a renaissance in high performance, high speed naturally aspirated gasoline engines, which are prized for their emotional contribution to the vehicle. In order to guarantee high conversion efficiency of a Three Way Catalyst in the exhaust system, an engine must be operated at stoichiometric air-fuel ratio. At high power density, this may result in very high exhaust gas temperature, which poses a risk to engine and vehicle hardware. A number of technological interventions to extend the maximum stoichiometric performance whilst respecting component limitations have already been described in the literature, but many of these are not applicable to specific engine architectures in

Corrigan, Dáire James, Villa, Davide, Penazzi, Eugenio, Meghani, Amit, Knop, Vincent, Caroli, Giacomo, Frigeri, Davide, Ruggiero, Federico, Malaguti, Simone, Postrioti, Lucio, Maka, Cristian

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