Browse Topic: Energy management

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Development of Emissions Prediction method by 1D-CAE and machine learning2025-32-0017To be published on 11/03/2025
In recent years, emissions regulations for engines have been globally strengthened, and many countries, including the United States, have added real-world testing using Portable Emissions Measuring Systems (PEMS) as new test requirements. In the development of diesel engines, improving fuel efficiency and simultaneously reducing NOx and soot emissions are critical challenges, and evaluations using Model-Based Development (MBD) are considered promising methods. However, it is still difficult to accurately predict soot emission, even with detailed combustion models using computationally intensive 3D-CFD, due to the complex mechanisms of soot formation. While various approaches have been researched for prediction methods, they are often limited to specific injection and operating conditions, and an industry-standard model has to be established yet. This paper presents a method for predicting NOx and soot emissions in diesel engines under arbitrary transient test cycles. Fuel consumption
Kitamura, TakahiroMatsuoka, AyanoSuematsu, KosukeOkano, Hiroaki
Technical Paper
Performance Analysis of a Hydrogen-blended Naturally Aspirated Gas Engine with a Dedicated Exhaust Gas Recirculation System2025-32-0046To be published on 11/03/2025
With the publication of the Renewable Energy Directive (RED) III in 2022, the European Union increased its renewable energy consumption target to 45% by 2030. Consequently, gaseous fuels derived from renewable electricity, particularly green hydrogen, are expected to play a pivotal role in the decarbonization of the energy sector. One promising application of green hydrogen is its integration into combined heat and power (CHP) plants, where it can replace natural gas to reduce CO₂ emissions. Pure hydrogen as fuel or blended with natural gas has demonstrated potential for lowering both pollutant emissions and fuel consumption while maintaining or even enhancing engine performance. But it is expected, that the amount of available green hydrogen will be limited in the beginning. So new engine systems with hydrogen and natural gas for CHP plants are required, that offer more CO2-benefit than from fuel substitution only. In the LeanStoicH₂ project, a novel approach was developed to optimize
Salim, NaqibBeltaifa, YoussefKettner, Maurice
Technical Paper
Ultralightweight Emission Measurement Systems for Motorcycles: Accuracy and Practicality in RDE Testing2025-32-0011To be published on 11/03/2025
Real Driving Emission (RDE) testing for motorcycles presents unique challenges due to the motorcycles lightweight construction, limited mounting space, and sensitivity to added mass and aerodynamic drag. Full-functional automotive Portable Emission Measurement Systems (PEMS), while highly accurate, are often impractical for two-wheelers as their weight and size can alter driving resistances, fuel consumption, and emission profiles, but also complicate installation and probably effect the drivability of the vehicle. To address these limitations, lightweight alternatives such as Mini-PEMS and ultralightweight alternatives such as Sensor-based Emission Measurement Systems (SEMS) offer compact, low-power solutions tailored for small vehicles. SEMS are typically equipped with lower cost sensors and low-tech gas conditioning systems compared to PEMS. Due to this these systems may not meet regulatory homologation requirements. Nevertheless, they provide justifiable accuracy for many real
Schurl, SebastianLienerth, PeterJaps, LeonidSchroeder, MatthiasSchmidt, StephanKirchberger, Roland
Technical Paper
Design and development of a novel automatic powershift transmission for battery-electric vehicles2025-32-0096To be published on 11/03/2025
The increasing adoption of battery-electric propulsion systems in small vehicles such as two- and 3-wheelers but even smalls cars has created a growing demand for technological advancements to improve their autonomy. Due to cost and weight constraints, these vehicles cannot incorporate highly sophisticated electric motors, as seen in the premium car sector. Therefore, achieving the best possible efficiency in urban and extra-urban commuting requires innovative solutions. One promising approach is the integration of a two-speed transmission into the drivetrain, which allows for load point shifting within the electric motor’s operating map. This strategy significantly reduces energy consumption while maintaining optimal performance. The presented research focuses on the design and development of a simple, cost-efficient two-speed transmission that provides a viable alternative to direct drive systems. While direct drive configurations are highly efficient, they often lack flexibility in
Tromayer, Juergen
Technical Paper
Study on Strategies for Improving Energy Consumption for Electric Vehicles2025-32-0092To be published on 11/03/2025
The growing adoption of electric vehicles (EVs) is central to reducing greenhouse gas emissions and achieving sustainability goals. However, the energy consumption of EVs remains a key challenge, impacting their operational efficiency, range, and environmental benefits. This paper explores various strategies to improve energy consumption in electric vehicles, focusing on advancements in battery technology, energy-efficient driving behaviors, regenerative braking systems, and the integration of renewable energy sources. Additionally, the role of vehicle design, lightweight materials, and aerodynamics in minimizing energy loss is examined. The study also highlights the potential of data analytics in optimizing energy usage by predicting driving patterns and adjusting power distribution. Furthermore, a review of infrastructure advancements such as fast-charging stations and smart grid integration is provided, illustrating their contribution to enhancing EV energy efficiency. The findings
Jain, GauravPathak, RahulGore, PandurangPREMLAL, P
Technical Paper
Experimental Study of HCNG on Single Cylinder 395cc Spark Ignition Engine for Performance and Exhaust Emission.2025-32-0050To be published on 11/03/2025
There is growing demand for energy utilization due to stricter environmental emission norms to reduce greenhouse gases and other threats posed due to the emissions are major motivation factors for researchers to adopt on strategic plans to decrease the usage of energy and reduce the carbon contents of fuels, the usage of hydrogen or blend of hydrogen with CNG as a fuel in internal combustion engines is the best option. As hydrogen has lower volumetric energy density and higher combustion temperature, pure hydrogen-fueled engines produce lower power output and much higher NOx emissions than gasoline-fueled engine at stoichiometric air-fuel ratio. Blending of hydrogen with CNG provides a blended gas termed as hydrogen-enriched natural gas (HCNG). HCNG stands for hydrogen enriched compressed natural gas and it combines the advantages of both hydrogen and methane. The addition of Hydrogen to CNG has potential to even lower the CNG emissions and is the first step towards promotion of a
Syed, Kaleemuddin
Technical Paper
Development of Supercharged Direct-injection Two Stroke Engine with Intake and Exhaust Valve for Series Hybrid (2nd Report) - To Realize Lean Burn -2025-32-0023To be published on 11/03/2025
The two-stroke engine has a small displacement and high performance, and therefore saves space when the engine is installed in a vehicle. Thus, the application of two-stroke engines to HEVs is a very effective means of reducing vehicle weight and securing engine space. On the other hand, the unfired element increases in the exhaust gas with a two-stroke engine because the air-fuel mixture is blown through to the exhaust system during the scavenging process inside the cylinder. Moreover, combustion becomes unstable due to the large amount of residual burnt gas in the cylinder. To solve these problems, we propose a two-stroke engine that has intake and exhaust valves that injects fuel directly into the cylinder. We previously reported the engine shape and the method that can provide high scavenging efficiency and stable combustion in such a two-stroke engine as the first report. In this second report, we report on the results of our research to improve fuel efficiency and realize low
Sakurai, YotaHisano, AtsushiSaitou, MasahitoIchi, Satoaki
Technical Paper
Clean cuts, clear conscience: Advanced engines, optimized tools, eco-friendly fuels2025-32-0087To be published on 11/03/2025
Handheld outdoor power equipment is used worldwide to shape and maintain the environment and are daily assistants in forestry, operated under very demanding environmental conditions. In the power tool sector, as elsewhere, the shift from petrol to battery-powered products is already well underway, especially for consumer applications. However, internal combustion engines will continue to be indispensable for professional users of power tools, who place the highest demands on their equipment in terms of performance and energy density. These power tools are often used in remote locations and thus far away from a possible charging infrastructure. To make a contribution to climate protection, biofuels and RFNBOs are necessary. The continuous optimization of engine technology and its overall system, including cutting tools (saw chain set, cutting wheel, etc.) is an important development goal of STIHL. The interaction between the saw chain, guide bar and power train are essential for optimal
Beck, Kai W.Maier, GeorgMüller, MatthiasLux, ThomasKölmel, ArminLochmann, HolgerMelder PhD, Jens
Technical Paper
A simulation approach for the impact assessment of an axial flux traction motor applied on road electric vehicle2025-32-0077To be published on 11/03/2025
In the transition towards sustainable mobility, Circular Design principles are crucial. For advanced components such as electric motors, the selection of technological solutions during the design phase must ensure not only optimal performance but also minimal environmental impact throughout the product's life cycle: production, use, and end-of-life. In the automotive sector, the use phase is particularly critical, as the efficiency of the traction system directly correlates with its environmental sustainability and the actual energy consumption. This research introduces a simulation-based approach to evaluate the use phase of an Axial Flux Electric Motor equipped with Permanent Magnets. While providing high performance for electric traction motors, these magnets are composed of Rare Earth Elements (REEs), such as Neodymium, classified as Critical Raw Materials (CRMs) due to their limited availability and environmental concerns associated with their extraction and processing. However
Guadagno, MaurizioBerzi, LorenzoPugi, LucaDelogu, Massimo
Technical Paper
Energy distribution of Friction and Moment of Inertia with compression in Start of SI Engine2025-32-0090To be published on 11/03/2025
In a general purpose of small SI engine, it is required to reduced fuel consumption under the operating conditions of repeated start and stop. In other words, the energy distribution during starting from 0 rpm to idling speed is an important factor of information. The SI engine needs to be driven by the motor at the starting, and its electrical energy must be minimized. However, the engine itself needs to accelerate during starting, and its electrical energy is affected by compression, friction and moments of inertia. The purpose of this research is to clarify experimentally the starting condition that minimizes this electrical energy. This research has made it possible to divide and measure the frictional and compressional loss and the loss due to the moment of inertia during engine acceleration. Specifically, the effect of the moment of inertia was eliminated by using a motor to keep the engine in a constant state of rotation. This allows the electrical energy used by friction to be
Matsuura, Yusuke
Technical Paper
Comparison of measurement methods for wheel bearing friction losses in component and vehicle testing2025-32-0100To be published on 11/03/2025
The increasing electrification of vehicle powertrains brings attention to components with a minor contribution to overall friction losses in research and development. Analysing these losses is essential for optimising the energy efficiency of modern vehicles. Wheel bearings are of particular interest in this context, as friction losses affect both the driving and recuperation phases. These losses are dependent on temperature, mechanical loads and the bearing integration into the vehicle. The analysis of friction losses and their dependence on the above factors is usually carried out by measurements on component test benches to allow an isolated evaluation. In contrast, the friction losses of the complete drive system are measured on powertrain test benches or roller dynamometers. In this context, the factors affecting the losses in wheel bearings may deviate from the measurements obtained on component test benches. The purpose of this paper is to analyse the effect of two different
Hartmann, LukasErxleben, LarsRebesberger, RonHenze, RomanSturm, Axel
Technical Paper
A Study on the Development of Optimal Brakes for Electric Vehicles Using Simulation2025-01-0345To be published on 09/15/2025
As the internal combustion engine vehicle change into the electric vehicle, we can use regenerative brake. It can improve not only the energy consumption, but also reduce the hydraulic brake usage. The less hydraulic brake usage mitigates the heat load on the brake disc. From this reason, the lightweight brake can be used in the electric vehicle. However, when the lightweight brake is applied, the brake NVH can be increased. The optimization design of the lightweight brake should be done to prevent the brake NVH. In this paper, the optimal brake disc thickness and brake interfaces are determined by using of disc heat capacity analysis. The lightweight brake should be optimized by using of the brake squeal analysis. We can verify the results from both analysis and tests. Finally, we can have the lightweight brake, which is competitive in terms of cost, weight and robust to the brake NVH
Kim, SunghoKim, JeongkyuHwang, JaekeunKang, Donghoon
Technical Paper
Durable aluminum alloys for brake disc and rotor applications2025-01-0358To be published on 09/15/2025
Lightweight materials are essential in reducing the overall weight and improving the efficiency and performance of ICE and electric vehicles. The use of aluminum alloys is critical in transitioning to a more energy sustainable and environmentally friendly future. The accessible combinations of high modulus to density and strength to weight ratios, as well as their excellent thermal conductivity, make them an ideal solution for weight reduction in vehicles, thereby improving fuel efficiency and reduce emissions generated during braking events. Aluminum alloys with high strength and lifetime thermal stability have been industrialized for usage in brake rotor applications. Amongst the most used aluminum alloys with high thermal stability are 2618 and 4032 used both in aerospace and automotive industries. However, when it comes to prolonging the life of a product at temperatures that exceed 200°C, these alloys will degrade their properties quickly within the first 300 hours. Therefore, a
Duchaussoy, AmandineLorenzino, PabloFranklin, JackTzedaki, Maria
Technical Paper
Impact of Return Spring Positioning on Brake Drag Forces and Gaps2025-01-0330To be published on 09/15/2025
This study investigates the impact of return spring positioning on brake drag forces and brake gaps in an S-Cam brake assembly. A detailed analysis reveals that the offset placement of the shoe return spring leads to a shoe tilting phenomenon, resulting in uneven brake gaps. This misalignment reduces the clearance on the dust cover side, increasing drag forces and adversely affecting brake performance, fuel efficiency, and liner wear. To address this issue, an optimized design is proposed, that effectively eliminates tilting, restores uniform brake gaps, and significantly reduces drag forces. Validation through dynamometer testing confirms the effectiveness of the revised spring placement in minimizing brake drag and improving system efficiency. By optimizing return spring positioning, the study highlights improvements in braking efficiency, extended brake liner life, and enhanced durability of the braking system. The findings underscore the importance of precise spring placement in S
Rajput, Ganeshambekar, PrasadPREMLAL, PMittal, Jayant
Technical Paper
Reducing Range Prediction Uncertainty in Heavy-Duty Electric Vehicles Using a Route-Informed Transformer-Based Model2025-24-0122To be published on 09/07/2025
Electrification of heavy-duty on-road trucks used for regional freight transportation is a viable option for fleets to reduce operational and maintenance costs and lower their carbon footprint. However, there is considerable uncertainty in projecting their daily range because highly variable payload mass, among other factors, confounds battery state of charge (SOC) prediction algorithms. Previous work by the authors proposed an electric vehicle range prediction model based on two parallel recurrent neural networks (RNNs). The first RNN used mean-variance estimation to output a predicted mean and variance, and the second used bounded interval estimation to provide bounds on the SOC required to complete a trip. The dual RNN approach resulted in estimating the remaining range and error bands of the SOC over the route. The previous work was limited because it did not incorporate driving conditions, like road type and ambient temperature, that affect driver behavior and energy consumption
Jayaprakash, BharatEagon, MatthewNorthrop, William F.
Technical Paper
Simulation based dynamic thermal emulation unit for thermal preconditioning and emulation of hardware components on the thermal testbed2025-24-0137To be published on 09/07/2025
Electrification of vehicles plays an important role in the transformation pro¬cess towards sustainable mobility in the individual and transport sector. As a result, new challenges must be met during the development process with regard to the vehicles overall energy management system. A key challenge is the development of thermal management systems to optimize overall vehicle efficiency and to minimize ageing effects of the powertrain com¬ponents while maintaining passenger comfort. Efficiency and ageing effects are highly dependent on the conditioning state of the powertrain components due to their high thermal sensitivity with simultaneously narrow thermal operating limits. Comfort functions like cabin air conditioning have to be fulfilled as well, which has to be considered by the thermal management system. To develop innovative solutions for thermal management systems at an early stage of the development process, thermal emulation can be used to substitute hardware components
Weimer, NikoHohenberg, GünterBeidl, ChristianFiore, LuisStenger, ErikSeib, Rico
Technical Paper
Zero-Carbon Port Fuelling for Heavy Propulsion Through a Recuperated Split Cycle Engine2025-24-0044To be published on 09/07/2025
Upcoming global emissions regulations demand innovation in heavy-duty road and marine transport. This research explores emissions-compliant concepts using both experiments and simulations focused on the Recuperated Split Cycle Engine (RSCE), which separates compression and expansion to enable internal heat recovery and quasi-isothermal compression. A single-cylinder research engine representing the expansion cylinder of an RSCE demonstrated direct injection diesel and port injection hydrogen co-firing. A validated Chemkin-Pro Multi-Zone model first reproduced, then extended this work, evaluating partial diesel substitution with hydrogen or ammonia alongside secondary working fluids (SWF’s liquid N₂, H₂O, NH₃). For the extension, two variants of the split cycle architecture were employed; the RSCE in combination with hydrogen fueling for the heavy-duty road sector, and the novel recuperated reformed split cycle engine (R2SCE), a new architectural and simulation contribution enabling on
Wylie, ElisaPanesar, Angad
Technical Paper
New Hybrid Powertrain architectures for European Passenger Car Market2025-24-0097To be published on 09/07/2025
The present paper describes a comparative analysis of different hybrid architectures and optimization of the total energy efficiency on passenger car applications. The first part of the study is devoted to providing simulation results of different type of hybrid architecture, highlighting their advantages and disadvantages with numerical simulation on different type of use cases, not only on legislated cycles but also on RDE use cases representative of customer behavior. The outputs of the usage of Passenger cars for the EU market highlights interesting results not yet published. The above mentioned analysis opens the window to (1) study new control strategies for optimizing the total energy consumption in different scenarios and (2) investigate options for maximizing the efficiency of the overall powertrain system.
Amati, NicolaMarello, OmarMancarella, AlessandroCavallaro, DavideIanni, LucaCascone, ClaudioPaulides, Johannes JH
Technical Paper
Effect of PEM Fuel Cell Technology Advancement on the Energy Efficiency of a Heavy-Duty Vehicle2025-24-0111To be published on 09/07/2025
Advancements in fuel cell stack technology—such as improved power density, catalyst utilization, and durability—have significantly enhanced system efficiency and reduced hydrogen consumption in heavy-duty fuel cell electric vehicles (FCEVs). In parallel, innovations in auxiliary subsystems, including air supply management, thermal regulation, and energy storage integration, have minimized parasitic losses, optimized fuel usage, and improved battery state-of-charge dynamics. These technological improvements collectively influence vehicle operation under varying load conditions, affecting both transient response and overall energy efficiency. To systematically assess these impacts, this study evaluates key performance metrics such as compressor-related energy losses, fuel utilization, and battery performance. The current vehicle simulation model relies on an outdated fuel cell system based on technology from 20 years ago, which no longer accurately reflects the efficiency potential of
Dursun, BeyzaJohansson, MaxTunestal, Peraronsson, UlfEriksson, LarsAndersson, Oivind
Technical Paper
Multilevel control strategy design and optimization for fuel cell hybrid heavy-duty vehicles2025-24-0107To 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 develops a multilevel control architecture that optimizes fuel economy and minimizes emissions in fuel cell hybrid heavy-duty vehicles, equipped with proton exchange membrane fuel cell and battery pack as main power sources. The detailed fuel cell system model incorporates reactants 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, membrane water content and differential pressure between the cathode and anode. By identifying optimal setpoints for key control variables, this methodology enables the development of accurate control maps for actuator management
Bove, GiovanniAliberti, PaoloSimone, ChristianSorrentino, MarcoPianese, Cesare
Technical Paper
Electric Machines with Reconfigurable Windings for Automotive Applications2025-24-0131To 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, JoshuaNoori Asiabar, AriaWang, BoHerzog, MaticTrinchuk, DanyloRomih, JakaVagg, Christopher
Technical Paper
The Effect of the Initial Battery State of Charge on the Performance of a Soft Actor-Critic Energy Management System2025-24-0104To be published on 09/07/2025
Reinforcement Learning (RL) approaches have gained significant popularity for solving complex optimization problems, such as the design of Energy Management Systems (EMS) in electrified powertrains, thanks to their adaptability and model-free nature. Therefore, this study investigates, through numerical simulations, the performance of an EMS, driven by a Soft Actor-Critic (SAC) RL agent targeting the reduction of CO2 emissions in a Plug-in Hybrid Electric Vehicle (pHEV). The SAC agent stands out with its stochastic policy, which accelerates the training process, boosts controller performance, and effectively handles the inherent uncertainties of vehicle dynamics. To improve generalization, the proposed controller was trained and validated across a wide set of driving scenarios. The robustness of the SAC policy was further demonstrated in charge depleting mode across various initial and final battery energy levels. Performance was then benchmarked against the Dynamic Programming (DP
Tresca, LuigiPulvirenti, LucaRolando, Luciano
Technical Paper
Waste Heat Recovery in Hydrogen fuelled Internal Combustion Engine2025-24-0108To be published on 09/07/2025
Waste Heat Recovery is one of the most investigated and promising technologies for energy transition in the transportation sector, since it consents to maintain the high-level technology of the present propulsion systems, based on Internal Combustion Engines, while increasing the overall engine and vehicle system efficiency. At the same time, the use of alternative fuels, like hydrogen, has the same crucial role to reduce harmful and greenhouse emissions, without overturn the existing mature technology. A hydrogen-fueled Internal Combustion Engine is proposed in this paper, equipped with two sections of waste heat recovery: a direct one, consisting in an additional turbine downstream the main turbocharger of the engine, and a second stage where an Organic Rankine Cycle (ORC) unit is bottomed in the exhaust line. The aim is to have an overall efficiency which is close to 40%, considering the mutual effect of the two-stage recovery and the engine equilibrium rearrangement. In fact, when
Di Battista, DavideCipollone, RobertoCorti, EnricoBrancaleoni, Pier PaoloDi Prospero, FedericoRavaglioli, Vittorio
Technical Paper
Vehicle Under-Hood Thermal Management: Development of a Reduced-Order Model for Accurate and Computationally Efficient Temperature Distribution Simulations2025-24-0118To 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, StefanoGrattarola, FedericoBaratta, MirkoGiraudo, GabrieleFrezza, DavideBartolucci, Lorenzo
Technical Paper
Influence of MPC based Driver Types on the Energy Consumption of Battery Electric Vehicles2025-24-0113To be published on 09/07/2025
Electric vehicles are increasingly important to reducing emissions and promoting sustainable mobility. Despite their advantages over conventional vehicles, the energy consumption of electric vehicles is heavily influenced by various factors such as driving behavior, elevation profile, and environmental conditions. In particular, the driving style plays a crucial role in determining range and energy consumption. This influence is also observed in the context of the Interreg project FreeE-Bus. This project focuses on the development of optimized charging management for electric buses in the public transport system of the Lake Constance region. Due to strict data protection regulations that prevent a detailed analysis of driver data, assessing the impact of driving styles is difficult. This paper addresses this issue by developing an innovative driver model that simulates different driver types and analyzes their effects on energy consumption. The driver model employs a Model Predictive
Konzept, AnjaReick, BenediktMiller, MariusRautenberg, PhilipStörzer, Martin
Technical Paper
Supervised Machine Learning Approach to Predict the Optimal Equivalence Factor for Predictive Energy Management Strategies of Plug-in Hybrid Electric Vehicles2025-24-0119To be published on 09/07/2025
Achieving minimal fuel consumption in map-based energy management strategies or equivalent consumption minimization strategies (ECMS) for Plug-in Hybrid Electric Vehicles (PHEVs) requires prior knowledge of the optimal equivalence factor (EF). This factor, which weights the fuel consumption of the internal combustion engine (ICE) and electric energy consumption, can be calculated if the exact driving profile is known. However, in real-world scenarios, the exact driving profile and consequently the optimal EF is unknown. This uncertainty motivates the use of predictive information to estimate this factor, aiming to enable fuel optimal control in real world driving. This paper presents a methodology to predict the optimal EF across various initial battery states of energy and real-world driving profiles using a regression model for a given powertrain configuration. Initially, the optimal EF is determined, and a range of possible input features based on driving profiles are calculated and
Kimmig, NikolaiSchlomann, Jan PhilippGoerke, DanielSchmiedler, StefanGeringer, BernhardHofmann, Peter
Technical Paper
Effects of the battery pack temperature on the energy management strategy and fuel consumption of a series hybrid quadricycle2025-24-0101To be published on 09/07/2025
Nowadays, a push towards decarbonisation to reduce the problem of environmental pollution is increasingly pressing. In the current automotive context, a tendency among the cars manufacturer to consider the development of hybrid vehicles is growing. Indeed, thanks to the battery downsizing due to the presence of the range extender (REx), a hybrid electric vehicle (HEV) allows to overcome the limitations of pure electric vehicles (EV) such as the infrastructure which is linked to the battery charging process. Moreover, the performance of battery in terms of efficiency and operating limits are strictly related to the temperature of battery pack and to the energy management strategy (EMS). The proposed work aims to analyse the performance of a series hybrid vehicle (S-HEV) depending on the temperature of battery pack and the EMS. The considered S-HEV is equipped with a hydrogen-fuelled internal combustion engine that is used as REx. First, a lumped thermal model of the battery pack is
Cervone, DavideSicilia, MassimoPolverino, PierpaoloPianese, Cesare
Technical Paper
Τesting and modeling of a passive SCR system for hydrogen engines2025-24-0082To 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 occasionally 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 associated
Zafeiridis, MenelaosAlexiadou, PanagiotaKoltsakis, Grigorios
Technical Paper
Modeling fuel consumption in a heavy-duty diesel truck under real-world driving conditions including cold-start operation2025-24-0096To 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, TeresaMujahid, TalhaMorrone, PietropaoloAlgieri, Angelo
Technical Paper
Methodological approach to Battery Electric Vehicle design: Energy-Based model development from a detailed Digital Twin2025-24-0098To be published on 09/07/2025
On the path to the decarbonization of the transport sector, the development of electric vehicles (EVs) is crucial to meeting the targets set by international regulatory bodies. EVs operate with zero tailpipe emissions and offer high energy efficiency and flexibility; however, challenges remain in achieving a fully sustainable electricity supply. In this context, powertrain design plays a fundamental role in determining vehicle performance and mission feasibility, which are strongly influenced by operating conditions and application characteristics, such as driving profiles and ambient temperature. A key challenge is the optimal sizing of components, particularly the battery pack and the electric motor. Therefore, a structured and methodological approach to powertrain design is essential to ensuring an optimal configuration. To this end, the project focuses on an integrated approach based on a master-and-slave modeling framework applied to a light-duty commercial vehicle at two levels
Bartolucci, LorenzoCennamo, EdoardoGrattarola, FedericoLombardi, SimoneMulone, VincenzoTribioli, LauraAimo Boot, Marco
Technical Paper
Multi-Objective Optimization of the Energy Management Strategy for Hybrid Electric Vehicles - Examination of Sensitivities between Fuel Consumption, Electric Driving and Driving Comfort2025-24-0103To 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, BastianEngbroks, LukasSchmiedler, StefanGeringer, BernhardHofmann, Peter
Technical Paper
An eco-charging strategy for heavy-duty electric vehicles via graph optimization2025-24-0116To be published on 09/07/2025
The adoption of heavy-duty electric vehicles (HDEVs) presents significant challenges in trip planning due to high energy consumption, limited battery capacity, and the reduced availability of high-power charging stations. Unlike passenger EVs, HDEVs require careful coordination of routing and charging decisions to ensure both operational efficiency and feasibility. This work proposes a graph-based optimization framework for eco-charging strategies that jointly optimizes energy consumption, travel time, and charging costs while considering road, traffic, and infrastructure constraints. The methodology relies on constructing first a routing graph, where nodes represent waypoints, and edges represent road links with attributes such as speed limits, traffic conditions, and energy consumption. This graph is then extended into a hypergraph, where nodes incorporate information about both vehicle location and state-of-charge (SOC), while edges represent either driving or charging actions. The
Zonetti, DanieleSciarretta, AntonioDe Nunzio, Giovanni
Technical Paper
A Critical Assessment of Phase Change Materials for Boosting EV Efficiency2025-24-0147To be published on 09/07/2025
Effective thermal management in battery packs is a key technology for enhancing the efficiency and longevity of battery electric vehicles (BEVs). Traditional active cooling systems can consume significant amounts of energy, thereby impacting the vehicle's overall efficiency. This paper explores the use of phase change materials (PCMs) as a complementary cooling technology, enabling both an improved active and an extended passive conditioning of battery packs. By leveraging the unique properties of PCMs, it is possible to partially operate the battery system without active cooling, thus reducing the overall energy consumption and improving vehicle autonomy. The phase change phenomenon further offers the benefit of a homogeneous temperature distribution within the battery pack. This study addresses the potential of PCMs as a thermal management solution for battery packs by firstly identifying suitable materials meeting requirements specific to such application. In addition, the paper
Fandakov, AlexanderNolte, OliverHerzog, AlexanderSens, Marc
Technical Paper
On a NMPC-based supervisory control logic for Energy Management purposes in Aeronautical Hybrid Propulsion Systems2025-24-0102To be published on 09/07/2025
Eco-sustainability is one of the main aspects focused on motor industries, including those related to air transport, which work to realize alternative propulsion systems, such as Hybrid Electric Propulsion Systems, for reducing CO2 emissions. Despite the minor CO2 emission produced by Hybrid Electric Propulsion Systems, these categories of propulsors require a proper control architecture for managing combustion and electric energies based on driver decisions and the flight mission set. A supervisory control logic, based on a Nonlinear Model Predictive Control (NMPC), is presented in this work to guarantee a specific State of Charge level of batteries coupled with the minimization of fuel consumption of an aeronautical Hybrid Propulsion System. These two goals are achieved by the designed NMPC, which provides the best amount of torque between the propulsors belonging to the analyzed aeronautical powertrain, consisting of an Internal Combustion Engine and an Electric Machine. The
Tordela, CiroFornaro, Enrico
Technical Paper
Comparing different electrical architectures for a parallel PEMFC-battery hybrid electric lightweight vehicle2025-24-0110To 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, MassimoCervone, DavidePolverino, PierpaoloPianese, Cesare
Technical Paper
Design of a Wide-Input Single-Phase Full-Bridge Power Converter for a Free-Piston Engine2025-01-5054To be published on 07/21/2025
Free-piston engines are new and efficient energy conversion devices that eliminate mechanical crankshafts. A wide-input power converter was needed as an electronic crankshaft for a free-piston engine to achieve efficient power generation control. A 20 kW single-phase full-bridge power converter that can operate over a wide-input voltage range was proposed in this paper to solve this problem. A current controller was designed by discussing the current flow of the power converters in four working modes, including forward electric, reverse electric, forward generation, and reverse generation. A model that considers the parasitic inductance on the wires in the circuit and the parasitic inductance and capacitance of each pole of the insulated gate bipolar transistor (IGBT) switch was established in this paper, and the accuracy of the model was verified through simulation in MATLAB/Simulink. The main parameters of the power converter, such as the absorption resistance and capacitance of the
Li, MengfeiXu, ZhaopingLiu, Liang
Technical Paper
Deep Reinforcement Learning–Based Control Strategy for Electro-Hydrostatic Active Suspension15-18-03-001607/09/2025
A DRL (deep reinforcement learning) algorithm, DDPG (deep deterministic policy gradient), is proposed to address the problems of slow response speed and nonlinear feature of electro-hydrostatic actuator (EHA), a new type of actuation method for active suspension. The model-free RL (reinforcement learning) and the flexibility of optimizing general reward functions are combined with the ability of neural networks to deal with complex temporal problems through the introduction of a new framework called “actor-critic”. A EHA active suspension model is developed and incorporated into a 7-degrees-of-freedom dynamics model of the vehicle, with a reward function consisting of the vehicle dynamics parameters and the EHA pump–valve control signals. The simulation results show that the strategy proposed in this article can be highly adapted to the nonlinear hydraulic system. Compared with iLQR (iterative linear quadratic regulator), DDPG controller exhibits better control performance, achieves
Wang, JiaweiGuo, HuiruDeng, Xiaohe
Journal Article
Data-Driven Vehicle Specification of Conventional and Electric Heavy-Duty Commercial Trucks for Improved Energy Consumption02-18-03-001807/09/2025
In the heavy-duty commercial trucks sector, selecting the most energy-efficient vehicle can enable great reductions of the fleet operating costs associated with energy consumption and emissions. Customization and selection of the vehicle design among all possible options, also known as “vehicle specification,” can be formulated as a design space exploration problem where the objective is to find the optimal vehicle configuration in terms of minimum energy consumption for an intended application. A vehicle configuration includes both vehicle characteristics and powertrain components. The design space is the set of all possible vehicle configurations that can be obtained by combining the different powertrain components and vehicle characteristics. This work considers Class 8 heavy-duty trucks (gross combined weight up to 36,000 kg). The driving characteristics, such as the desired speed profile and the road elevation along the route, define the intended application. The objective of the
Villani, ManfrediPandolfi, AlfonsoAhmed, QadeerPianese, Cesare
Journal Article
Thermal Interaction Based on Battery Electrochemical Modeling for In-Wheel Hub Motor Electric Vehicles: A Performance Analysis14-14-03-001607/09/2025
As the adoption of battery electric vehicles (BEVs) continues to rise, analyzing their performance under varying environmental conditions that affect energy consumption has become increasingly important. A critical factor influencing the efficiency of BEVs is the heat loss from the operation and interaction between the vehicle components, such as the battery and motor, and the surrounding temperature. This study presents a comprehensive analysis of the thermal interaction in BEVs by integrating hub motor vehicle and battery electrochemical model with environmental factors. It explores how ambient temperature variations influence the performance of EV components, particularly the motors and battery systems, in both hot and cold weather conditions. The simulations also consider the passenger comfort inside the cabin as it investigates the effects of operating the air-conditioning system on overall energy consumption, revealing significant energy consumption shifts during extreme ambient
Abdullah, MohamedZhang, Xi
Journal Article
A New Electrified Planetary Gear Set - The Cost- and Fuel-Efficient Alternative to Continuously Variable Transmissions2025-01-030907/02/2025
In order to mitigate the effects of climate change, the global transport sector, one of the largest emitters of CO2, needs to drastically reduce its emissions. Although hybridization and electrification are becoming increasingly popular as a solution for a variety of applications, their use in two- and three-wheelers, as well as in recreational and powersports vehicles, remains limited due to their high costs and complexity compared to conventional drivetrains with continuously variable transmissions (CVTs). Despite their affordability and simplicity, CVTs suffer from low mechanical efficiency, with transmission losses ranging from 20–50 %, highlighting a significant opportunity for improvement. In response to these limitations, this study presents the development and experimental evaluation of an electrified planetary gear set (ePGS) in a lightweight off-road vehicle. It is designed to overcome the efficiency limitations of CVTs while maintaining high driving comfort and low system
Jakoby, MoritzEngels, MichaelFahrbach, TimmAndert, Jakob
Technical Paper
Improving Speed Trajectory Optimization for Electric Vehicles with Pre-Calculated Energy Maps and Dynamic Profile Discretization2025-01-031807/02/2025
Ongoing research and development in the field of electric vehicles (EVs) have resulted in a continuous expansion of their range. Additionally, advancements in vehicle connectivity have created new opportunities for intelligent driving assistance and energy optimization, particularly through the use of cloud data. However, the integration of eco-driving assistance with numerical optimization of speed trajectories remains challenging due to the high computational demands of these methods. To address this challenge and make such a system feasible for integration into vehicle systems, the computational effort required for an optimized driving trajectory must be minimized. This paper presents a method to accelerate speed trajectory optimization using pre-calculated energy and time consumption maps. For this purpose, a dynamic discretization of the anticipated driving profile is applied. Initial results show a substantial reduction in computation time, varying with different scenarios
Schilling Johnson, ReneHenke, Markus
Technical Paper
Effect of Gasoline Component on Fuel Economy of WLTC Drive with EGR and Lean Combustion2025-01-030507/02/2025
It is becoming increasingly clear that research into alternative fuels, including drop-in fuels, is essential for the continued survival of the internal combustion engine. In this study, the authors have evaluated olefinic and oxygenated fuels as drop-in fuels using a single-cylinder engine and considering fuel characteristic parameters. The authors have assessed thermal efficiency by adding EGR or excess air from zero to the maximum value that allows stable combustion. Next, we attempted to predict fuel efficiency for four types of passenger cars (Japanese small K-car N/A, K-car T/C, Series HV, and Power-split HV) by changing the fuels. We created a model to estimate fuel efficiency during WLTC driving. The results indicated that fuel economy could potentially be improved by adding an olefin fuel that burns stably even with a large amount of EGR or air and an oxygen fuel whose octane number increases. It was observed that the fuel economy improvement rate was particularly notable for
Moriyoshi, YasuoXu, FuguoWang, ZhiyuanTanaka, KotaroKuboyama, Tatsuya
Technical Paper
Optimized Cabin Heating Strategy for Battery Electric CEP Vehicles2025-01-026307/02/2025
Electromobility is gaining importance in the courier, express and parcel (CEP) sector, as parcel service providers increasingly rely on zero-emission vehicles to improve their CO₂ footprint. A common drawback of battery electric vehicles is their reduced range under cold operating conditions, due to the increased energy demand for cabin heating. Another CEP-specific factor influencing both energy consumption and cabin comfort is the frequent opening of doors during parcel delivery. Additionally, during delivery phases, the cabin cools down in the driver’s repeated absence from the cabin, as the heating is inactive. Nonetheless, a sufficient level of thermal comfort must be maintained during the driving phases between delivery stops. This paper presents an optimization-based strategy for the cabin heating of battery electric CEP vehicles. The objective is to maximize cabin comfort during driving phases while maintaining efficient energy consumption. For this purpose, a nonlinear model
Rehm, DominikKrost, JonathanMeywerk, MartinCzarnetzki, Walter
Technical Paper
Applying Real World Traffic Data on Machine Learning Methods for Graph Based Cooperation Strategies of Automated Vehicles2025-01-028607/02/2025
With the increasing distribution of smart mobility systems, automated & connected vehicles are more and more interacting with each other and with smart infrastructure using V2X-communication. Hereby, the vehicles’ position, driving dynamics data, or driving intention are exchanged. Previous research has explored graph-based cooperation strategies for automated vehicles in mixed traffic environments based on current V2X-communication standards. Thereby, the focus is set on cooperation optimization and maneuver negotiation. These strategies can be implemented through both centralized and decentralized computational approaches and are conflict-free by design. To enhance these previously established cooperation models, real-world traffic data is used to derive vehicle trajectories, providing a more accurate representation of actual traffic scenarios in order to enhance the practical application of the described methodology. Additionally, machine learning algorithms are employed to train
Flormann, MaximilianMeyer, FelixHenze, Roman
Technical Paper
Simulation-Based Investigation and its Experimental Validation of the Thermal Behaviour of a Battery Electric City Bus2025-01-026607/02/2025
Electrification of city busses is an important factor for decarbonisation of the public transport sector. Due to its strictly scheduled routes and regular idle times, the public transport sector is an ideal use case for battery electric vehicles (BEV). In this context, the thermal management has a high potential to decrease the energy demand or to increase the vehicles range. The thermal management of an electric city bus controls the thermal behaviour of the components of the powertrain, such as motor and inverters, as well as the conditioning of the battery system and the heating, ventilation, and air conditioning (HVAC) of the drivers’ front box and the passenger room. The focus of the research is the modelling of the thermal behaviour of the important components of an electric city bus in MATLAB/Simscape including real-world driving cycles and the thermal management. The heating of the components, geometry and behaviour of the cooling circuits as well as the different mechanisms of
Schäfer, HenrikMeywerk, MartinHellberg, Tobias
Technical Paper
Investigation on Thermal Management of Heavy-Duty Commercial FCEV with Focus on Vehicle System Efficiency2025-01-026507/02/2025
The primary approach to meet the objectives of the EU Heavy Duty CO2 Regulation involves decarbonizing the road transport sector by battery electric vehicles (BEV) or hydrogen-fueled vehicles. Even though the well-to-wheel efficiency of hydrogen-fueled powertrains like fuel cell electric vehicles (FCEV) and H2-internal combustion engines (H2-ICE) is much lower in comparison to BEV, they are better suited for on-road heavy-duty trucks, long haul transport missions and regions with scarce charging infrastructure. Hence, this paper focuses on heavy-duty FCEVs and their overall energetic efficiency enhancement by intelligently managing energy transfer across coolant circuit boundaries through waste heat recovery, while ensuring that all relevant components remain within required temperature boundaries under both cold and hot ambient conditions. Results were obtained using a 1D-model that comprises all thermal fluid circuits (refrigerant, coolant, air) created through GT-Suite software
Uhde, SophiaLanghorst, ThorstenWuest, MarcelNaber, Dirk
Technical Paper
Experimental Evaluation of Purge Strategies in the Recirculation Path of a PEM Fuel Cell System2025-01-031607/02/2025
PEM fuel cell technology plays a vital role in realizing an emission-free mobility and, depending on the considered use case, offers significant advantages over battery electric solutions as well as hydrogen combustion engines. When high performance over a longer period of time as well as short refueling times are key requirements, fuel cell powertrains show their core strengths. However, the adaption of fuel cells in the mobility sector strongly depends on their efficiency which directly relates to the vehicle’s fuel consumption, range and ultimately cost to operate. Therefore, the influence on efficiency and power of different purge strategies used to operate PEM fuel cells is experimentally investigated and compared. A concentration-dependent purge strategy is developed and examined in reference to a charge-dependent strategy. The measurements are carried out on a fuel cell system test bench which corresponds to a fully functional fuel cell system including all commonly used
Hauser, TobiasAllmendinger, Frank
Technical Paper
Modular Thermal Management Framework for Electric Drive System Development2025-01-026207/02/2025
The automotive industry is undergoing a major shift from internal combustion engines to hybrid and battery electric vehicles, which has led to significant advancements and increased complexity in drivetrain design and thermal management systems. This complexity reflects the growing need to optimize energy efficiency, extend vehicle range, and ensure system reliability in modern electric vehicles. At the Institute of Automotive Engineering, a specialized synthesis tool for drivetrain optimization is used to identify the best drivetrain configurations based on specific boundaries and requirements. Building up on this toolchain a modular and adaptable thermal management framework has been developed, addressing another critical aspect of vehicle and drive development: efficient thermal circuit layout and its impact on energy consumption and overall system reliability. The thermal framework emphasizes the dynamic interactions between key components, such as electric machines, power
Notz, FabianSturm, AxelSander, MarcelKässens, ChristophHenze, Roman
Technical Paper
Computational Investigation of Advanced Compression Ignition with Wet Ethanol in an OP-2S04-19-01-000206/30/2025
Alcohol fuels have inherent properties that make them suitable candidates to replace conventional fossil fuels in internal combustion engines by reducing the formation of harmful emissions such as lifecycle carbon dioxide (CO2), nitrogen oxides (NOX), and particulate matter (PM). There is an increasing amount of work to use fuels such as ethanol or methanol in mixing-controlled compression ignition (MCCI) as a replacement for diesel fuel. However, employing these fuels in a strictly MCCI strategy results in an evaporative cooling penalty that lowers indicated fuel efficiency. This work proposes the use of an advanced compression ignition (ACI) strategy with a high autoignition resistant fuel, where a fraction of the fuel is premixed and autoignited in conjunction with a fraction of fuel that is burned in a mixing-controlled manner to achieve diesel-like efficiencies with significant emission reductions. A computational model for MCCI with diesel and wet ethanol in an opposed piston two
O’Donnell, Patrick ChristopherGainey, BrianBhatt, AnkurHuo, MingLawler, Benjamin
Journal Article
Learning-Based Predictive Controller for Connected and Automated Hybrid Electric Vehicles14-14-02-001506/19/2025
This article aims at presenting a learning-based predictive control strategy for hybrid electric vehicles (HEVs) in the presence of uncertainty, where the controller structure and energy efficiency of the HEV is simultaneously optimized. The proposed approach includes development of a Bayesian optimization (BO)–based control structure optimization method, followed by an eco-driving–based hierarchical robust energy management strategy (EMS) development for connected and automated HEVs. To apply the learning-based strategy online, we also introduce an approach with approximate cost function for the BO to reduce training and computation time and improve energy in a given trip. The control structure is described by a parameter vector, which is updated, using BO, in an episodic fashion with the performance of the EMS and the computation time. With the current control structure, the hierarchical EMS includes a high-level powertrain energy manager that takes long-term decisions, and a low
HomChaudhuri, BaisravanIranzo Juan, Ignacio
Journal Article
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