Browse Topic: Fuels and Energy Sources

Items (37,094)

Decarbonization of Off-Road Engines by Methanol Mixing-Controlled Compression Ignition with Ignition Enhancer

2025-01-8411To be published on 04/01/2025

Methanol is one of the most promising fuels for the decarbonization of the off-road and transportation sectors. Although methanol is typically considered an alternative fuel for spark ignition engines, mixing-controlled compression ignition (MCCI) combustion is typically preferred in most off-road and medium-and heavy-duty applications due to its high reliability, durability and high-efficiency. In this paper, methanol MCCI combustion was enabled using ignition improvers and the potential benefits of this approach compared to conventional diesel combustion were investigated. Methanol was blended with 7%vol 2-ethylhexyl nitrate (EHN) and experiments were performed in a single-cylinder production-like diesel engine with a displacement volume of 0.83 L and a compression ratio of 16.5: 1. The conditions of the ISO 8178 C1 regulatory cycle for off-road engines were tested, and performance and emissions over the cycle were calculated. Methanol MCCI shows 6.5% lower fuel consumption (in

Lee, Sanguk, Lopez Pintor, Dario, MacDonald, James, Narayanan, Abhinandhan, Chan, Adrian

Robust Predictive Cruise Control for Class 8 Trucks Considering Traffic Light Timing

2025-01-8033To be published on 04/01/2025

An implementation of a robust predictive cruise control method for class 8 trucks utilizing V2X communication with connected traffic lights is presented in this work. This method accounts for traffic signal phases with the goal of reducing energy consumption while maintaining reasonable travel speed and respecting safety concerns. Tightened constraints are created using a robust model predictive control (RMPC) framework in which constraints are modified so that the safety critical requirements are satisfied even in the presence of disturbances, while requiring only the expected bounds of the disturbances to be provided. In particular, variation in the actuator performance under different conditions presents a unique challenge for this application, which the approach applied in this work is well-suited to handle. The errors resulting from lower-level control and actuator performance are accounted for by treating them as bounded and additive disturbances on the states of the model used

Ellison, Evan, Ward, Jacob, Brown, Lowell, Bevly, David

Verification of the Impact of Coefficient of Drag Variation due to Natural Wind on Fuel Consumption based on Actual Driving Data

2025-01-8778To be published on 04/01/2025

It is often assumed that the actual fuel economy on public roads is affected by natural wind and that this could be contributing to discrepancy between catalog fuel economy and actual fuel economy, owing to the increased yaw angle and drag coefficient (CD). However, the impact of yaw characteristics alone on fuel economy during actual driving has not been verified or proven as it is difficult to obtain actual driving data under uniform conditions. For this reason, shape optimization is normally performed at zero-yaw through the aerodynamic development phases. In this paper, two vehicles with different yaw sensitivity characteristics are driven simultaneously, and fuel economy measurements are performed simultaneously with ambient airflow, environment, and vehicle conditions, and the results where the conditions of the two vehicles match are extracted to clarify the impact of the differences of yaw characteristics on fuel economy. The obtained results matched the values predicted by

Onishi, Yasuyuki, Nichols, Larry, Metka, Matt, masumitsu, Yasutaka, Inoue, Taisuke

Optimization method of phase change energy storage device for electric vehicle batteries based on numerical simulation

2025-01-8603To be published on 04/01/2025

Phase change energy storage devices are extensively utilized in latent heat thermal energy storage and hold significant potential for application in the thermal management of automotive batteries. By harnessing the high-density energy storage capabilities of phase change materials to absorb heat released by the batteries, followed by timely release and utilization, there is a substantial improvement in energy efficiency. This approach aligns with the objective of promoting low-carbon environmental protection and presents an opportunity to enhance the operational performance and energy utilization efficiency of electric vehicle batteries in low-temperature conditions. However, the thermal conductivity of medium and low temperature phase change materials is poor, leading to its inefficient utilization. This paper focuses on optimizing the structure of a phase change heat exchanger in a phase change energy storage device to improve its performance. A basic design of the phase change heat

Zhang, Haonan, Sun, Mingzhe, Zheng, Haoyun, Zhang, Tianming

European Initiatives addressing High efficiency and low cost electric motors for circularity and low use of rare resources

2025-01-8806To be published on 04/01/2025

The automotive industry is amidst an unprecedented multi-faceted transition striving for more sustainable passenger mobility and freight transportation. The rise of e-mobility is coming along with energy efficiency improvements, CO2 and non-exhaust emission reductions, driving/propulsion technology innovations, and a hardware-software-ratio shift in vehicle development for road-based electric vehicles. Current R&D activities are focusing on electric motor topologies and designs, sustainability, manufacturing, prototyping, and testing. This is leading to a new generation of electric motors, which is considering recyclability, reduction of (rare earth) resource usage, cost criticality, and a full product life-cycle assessment, to gain broader market penetration. This paper outlines the latest advances of multiple EU-funded research projects under the Horizon Europe framework and showcases their complementarities to address the European priorities as identified in the 2ZERO SRIA . The E

Armengaud, Eric, Ratz, Florian, Muñiz, Ángela, Poza, Javier, Garramiola, Fernando, Almandoz, Gaizka, Pippuri-Mäkeläinen, Jenni, Clenet, Stéphane, Messagie, Maarten, D’amore, Lea, Lavigne Philippot, Maeva, Rillo, Oriol, Montesinos, Daniel, Vansompel, Hendrik, De Keyser, Arne, Romano, Claudio, Montanaro, Umberto, Tavernini, Davide, Gruber, Patrick, Ran, Liaoyuan, Amati, Nicola, Vagg, Christopher, Herzog, Matic, Weinzerl, Martin

On-Road Investigation of Energy Saving Opportunity for Autonomous Light-Duty Vehicles through Automated Vehicle-Following in Safe Distance Scenarios

2025-01-8029To be published on 04/01/2025

Reducing aerodynamic drag through vehicle following is one of the energy reduction methods for connected and automated vehicles with advanced perception systems. This paper presents the results of an experimental investigation aimed at assessing energy reduction in manually driven light-duty vehicles through on-road tests of reducing the aerodynamic drag by vehicle following. This study provides insights into the effects of lateral positioning in addition to intervehicle distance and vehicle speed, and the profile of the lead vehicle. A series of tests were employed to analyze the impact of these factors, conducted under realistic driving conditions. The research encompasses various light-duty vehicle models and configurations, with advanced instrumentation and data collection techniques employed to quantify energy-saving potential. The study featured a two set of L4 capable light duty vehicles, including the Stellantis Pacifica PHEV minivan and Stellantis RAM Truck, examined in

Poovalappil, Aman, Robare, Andrew, Schexnaydre, Logan, Santhosh, Pruthwiraj, Bahramgiri, Mojtaba, Bos, Jeremy P., Chen, Bo, Naber, Jeffrey, Robinette, Darrell

Platform Development of Fuel Cell Air Compressors and Turbine Expanders

2025-01-8547To be published on 04/01/2025

Hydrogen fuel cell is one of paths to achieve carbon neutrality transportation. In the last two decades, significant improvements have been made in compactness, efficiency and durability of fuel cell systems. For heavy duty truck applications, a life span similar to heavy duty diesel engines is required. As a critical component in the fuel cell system, air compressors play an important role to meet fuel cell systems’ high efficiency and durability requirements. In this paper, a holistic approach has been taken to develop a series of airfoil bearing centrifugal compressors for a wide range of applications from forklift, passenger vehicles to commercial vehicles, and achieve high efficiency and durability of one million start-stops. In the new platform development, cooling circuit was optimized so that the external cooling air circuit for the rotor and air bearings is no longer needed, which resulted in 4% efficiency improvement. Hollow rotor structure was adopted to achieve lightweight

Wang, Qianzhen, Yuan, Xixin, Tao, Zhang, Feng, Jin Zeng, Wang, Juan, Xiao, Yong, Zhou, Lei, Xin, Jun

A MIL/SIL Testing Approach for Predictive Energy Management Algorithms

2025-01-8583To be published on 04/01/2025

Energy management strategy is essential for HEV’s to achieve an optimum of energy consumption. With predictive energy management, taking future vehicle speed predicted from ADAS map information, in-vehicle navigation traffic flow status information, and current speed into account, one could anticipate a considerable improvement in energy-saving. The major validating approach widely adopted for energy management algorithms nowadays is real-world vehicle testing, of which the economic and time costs are relatively high. Moreover, with advanced algorithms featuring AI coming into light, putting forward higher requirement in the richness of test cases, the drawback in coverage of vehicle testing is revealed. This paper proposed a MIL/SIL testing approach for predictive energy management algorithms, providing an alternative to, and overcome the limitations of, vehicle testing. In the testing setup, random traffic would be generated by MATLAB based on real-time traffic condition queried from

Yan, Yue, Ma, Xiudan

Innovative Use of Basic Technologies for a High-Efficiency, Low-Cost Small Displacement Gasoline Engine

2025-01-8392To be published on 04/01/2025

In recent years, world-wide automotive manufacturers have been continuously working in the research of suitable technical solutions to meet upcoming stringent Corporate Average Fuel Economy (CAFÉ), Worldwide harmonized Light vehicles Test Cycles (WLTC) and Real Driving Emission (RDE) targets, as set by international and country’s local regulatory authorities. Many technologies have already been developed or are currently under study by automotive manufacturers for gasoline engines, to meet legislated targets. In-line with the above objective, Maruti Suzuki Engine Design and Development team worked to enhance the efficiency of a small gasoline engine (i.e 0.8 L) applicable for small entry level 5-door hatchback vehicles. Improvements were made in the engine’s thermal and mechanical efficiencies with minimum cost increment considering stringent entry level vehicle cost target. These improvements help to attain the minimum BSFC along with increasing the minimum BSFC area in engine map to

Singh, Amandeep, Singh, Jaspreet, Jalan, Ankit, Kumar, Narinder

Experimental investigation between pre-ignition, knocking, vibration and performance in an internal combustion engine

2025-01-8380To be published on 04/01/2025

Otto cycle internal combustion engines have undergone technological developments that can be fueled by various types of fuels in different mixture proportions. To achieve this, a detailed study of the main factors that influence the engine combustion process is necessary. The objective of this study is to evaluate the effects of varying the ignition advance on the performance parameters and vibration level of the engine operated with regular gasoline, podium gasoline, ethanol and a mixture of ethanol with regular gasoline. The experimental tests consisted of operating an Otto cycle engine on a bench dynamometer under full load conditions, varying rotation and ignition advance by 5, 10 and 20% in relation to the original ignition advance and correlating the levels of pre-ignition, knock, engine vibration levels with engine performance parameters. The results showed that the engine vibration level was influenced by the type of fuel used, engine performance parameters and the presence of

Santana, Claudio

Comprehensive gear shift schedule of heavy-duty commercial electric trucks based on dual axle driving

2025-01-8510To be published on 04/01/2025

A heavy-duty commercial electric truck is equipped with dual axles, with the middle axle driven by an electric motor and a three-speed transmission and the rear axle driven by an electric motor and a two-speed transmission. To consider the dynamics and economic performance of the whole vehicle, as well as the gear distribution characteristics in the vehicle operation, a comprehensive shifting law based on the cross-particle swarm algorithm is proposed. By establishing the longitudinal dynamics model of the truck, the optimal power shift schedule and the optimal economic shift schedule of each of the two transmissions are studied. Under the standard test conditions, an optimal gear control strategy based on the dynamic programming algorithm considering the shift interval is proposed, and the shift schedule for the standard conditions is derived through the hierarchical clustering method. Furthermore, with 100 km acceleration time and specific energy consumption as the objectives, a

Guo, Jun, Zhang, Yunqing, Wu, Jinglai

Optimal Hybrid Drive Configuration for Synthesized ICE

2025-01-8534To be published on 04/01/2025

In order to reduce the emission in individual traffic electrification and hybridization is needed. The emission reduction depends on the degree of electrification and the specific drive system design and optimized components. This applies especially for hybrids with the highest amount of components, consisting of internal combustion engine, transmissions, electric motors and batteries. With the integration of the EM in the transmission for dedicated hybrid transmissions, the amount possible solutions and variants lies in the billions. Hence for the development of new drive architectures computer aided drive synthesis are needed. In a DFG funded project we developed a drive synthesis, including an ICE synthesis as well as transmission synthesis. The syntheses are controlled via an artificial intelligence based control algorithm including engineering knowledge. In this paper we are focusing on the impact the ICE concept has on the drive system dimensioning, the fuel economy, performance

Sturm, Axel

The development and real-time application of DP-based optimized A-ECMS algorithm for multi-mode series-parallel hybrid electric vehicles

2025-01-8589To be published on 04/01/2025

The hybrid electric drive system shows its great potential in the energy sustainability of the automotive industry. This paper investigates the improved adaptive equivalent consumption minimization strategy (A-ECMS) for a multi-mode series-parallel hybrid electric vehicle. First, a basic ECMS algorithm for the series-parallel vehicle is established, which considers the instantaneous optimal torque matching in the electric, serial hybrid, and engine driving modes. Then, Genetic Algorithms (GA) are used for offline global optimization of the equivalent factor and penalty function exponent. Under the condition that the future traffic information scenario is known, it is desired to realize the global optimal planning based on the combination of dynamic programming (DP) and ECMS. Therefore, the SOC, engine speed, and torque results calculated by the DP strategy are used as benchmarks to develop the improved SOC-AECMS and S-AECMS strategies, which better incorporate the advantages of the

Zhu, Jingyu, Han, Mengwei, Liu, Chongfan, Yang, Chenfan

Morphologies and structures of liquid fragments derived from the near-field zone of a twin-orifice swirl atomizer

2025-01-8461To be published on 04/01/2025

Aviation gas turbine engines typically utilize twin-orifice swirl atomizers to achieve a fine spray, widen the spray cone angle, and shorten spray penetration. However, using twin-orifice atomizers complicates the spray structure, and knowledge of the spray, especially in the near-field nozzle zone, remains limited. This study experimentally investigates the morphologies and structure of liquid fragments in the near-field nozzle of a twin-orifice atomizer. A high-speed backlit experimental system was developed to examine the liquid fragment morphologies and structures. The fragments are classified into spherical droplets, ligaments, and other irregular structural fragments. Results show that with increasing the pressure in the near field of the nozzle, the proportion of nearly round fragments decreases with increasing pressure. In contrast, the proportion of ligament-like fragments tends to increase. Besides, the particle size distribution did not change significantly within the 10 to

Pham Vu, Nam, Manh, Vu, Pham, Phuong Xuan, Nguyen, Kien Trung

European initiatives for User-Centric design of Electric Vehicle

2025-01-8807To be published on 04/01/2025

E-mobility is revolutionizing the automotive industry by improving energy efficiency, lowering CO2 and non-exhaust emissions, innovating driving and propulsion technologies, redefining the hardware-software-ratio in the vehicle development, facilitating new business models, and transforming the market circumstances for electric vehicles (EVs) in passenger mobility and freight transportation. Ongoing R&D action is leading to an uptake of affordable and more energy efficient EVs for the public at large through the development of innovative and user-centric solutions, optimized system concepts and components sizing, and increased passenger safety. Moreover, technological EV optimizations and investigations on thermal and energy management systems as well as the modularization of multiple EV functionalities result in range maximization, driving comfort improvement, and greater user-centricity. This paper presents the latest advancements of multiple EU-funded research projects under the

Ratz, Florian, Bäuml, Thomas, Kompara, Tomaž, Kospach, Alexander, Simic, Dragan, Jan, Petra, Möller, Sebastian, Fuse, Hiroyuki, Parades Barros, Esteban, Armengaud, Eric, Amati, Nicola, Sorniotti, Aldo, Lukesch, Walter

Comparison of Gasoline Particulate Indices Using U.S. Market Gasoline Samples

2025-01-8449To be published on 04/01/2025

Simulated distillation (SimDis) uses wide bore capillary gas chromatography (GC) to provide a detailed volatility profile of blended gasoline. The boiling point distribution from SimDis analysis is correlated to the hydrocarbon contents of spark ignition fuels and provide the resolution necessary to characterize the compositions of the fuel. Recent publications on simulated distillation applied to spark ignition fuel reveal the merits of indexing a gasoline fuel so that it can be correlated to the tendency of particulate emissions from vehicles. With this in mind, SimDis can be a useful and quick tool in assessing the PM-formation potential of market gasolines. Heavy aromatic compounds that are present in spark ignition fuels are major contributors to vehicle particulate emissions. These compounds are present in the higher boiling portion (T70+) of the distillation profiles. As demonstrated in recent studies, the particulate indices of gasoline samples are indicative of the relative

Goralski, Sarah, Geng, Pat, Dozier, Jon, Butler, Aron

Model-Predictive Control for Heat Pump-Based Battery Thermal Management in Off-Road Autonomous Electrified Vehicles During Transient Operation

2025-01-8184To be published on 04/01/2025

The shift towards hybrid and electric powertrains in off-road vehicles aims to enhance mobility, extend range, and improve energy efficiency. However, heat pump-based thermal management systems in these vehicles continue to consume significant energy, impacting overall range and efficiency. Effective thermal management is essential for maintaining battery performance and safety, particularly in extreme conditions. Although high-fidelity models can capture the complex dynamics of heat pumps, real-time control within model-based optimization frameworks often depends on simplified models, which can degrade system performance. To address this, we propose a novel data-driven grey box control-oriented model (COM) that accurately represents the thermal dynamics of a vapor-compression refrigeration-based heat pump system. This COM is integrated into a model-predictive control (MPC) framework, optimizing thermal management during transient and burst-power operations of the battery pack. We

Sundar, Anirudh, Ghate, Atharva, Zhu, Qilun, Prucka, Robert, Ruan, Yeefeng, Figueroa-Santos, Miriam, Barron, Morgan

Energy consumption optimization of commercial electric bus in Indian city driving condition using two speed transmission

2025-01-8504To be published on 04/01/2025

ABSTRACT Currently automobile industries are shifting towards electric powertrains from conventional internal combustion engines. With increase in use of electric vehicle, more focus is to increase the driving range of vehicle. As of now, most of the OEMs are using single speed transmission in their electric buses. Single speed transmission is effective in road having less traffic condition but during heavy traffic condition (like Mumbai city application), performance of motor gets deteriorated. In heavy traffic condition (city application), operating points of motor goes into less efficiency regions which results in high energy consumption. It will also affect the regeneration. In this study, focus is on commercial vehicle like electric buses. If there is a need to increase driving range, energy consumption must be optimized. Thus, higher energy consumption in heavy traffic condition can be managed by using multiple gear ratio. With use of optimum gear ratio, motor operating points

Saurabh, Saurabh, Amancharla, Naga Chaithanya, Bhardwaj, Rohit, Gadve, Dhananjay

Fuel Consumption Estimation Using Spatio-Temporal Modeling and Traffic Flow Predictions: A Comparative Analysis

2025-01-8101To be published on 04/01/2025

Effective traffic management and energy-saving techniques are increasingly needed as metropolitan areas grow and traffic volumes rise. This work estimates fuel consumption over three selected routes in an urban context using spatio-temporal modeling essentially building on a previously developed approach in traffic prediction and forecasting. A weighted adjacency matrix for a Graph Neural Network (GNN) is constructed in the original approach which combines graph theory frameworks with travel times obtained from average speeds and distances between traffic count stations. Next, the traffic flow estimate uncertainty is measured using Adaptive Conformal Prediction (ACP) to provide a more reliable forecast. This work predicts fuel consumption under different scenarios by utilizing Monte Carlo simulations based on the expected traffic flows providing insights into energy efficiency and the best routes to take. The study compares passenger vehicles' and heavy-duty trucks' mean fuel

Patil, Mayur, Moon, Joon, Hanif, Athar, Ahmed, Qadeer

A Conjugate Heat Transfer Numerical Framework Applied to Energy-Assisted Ignition of Jet Fuel in a Rapid Compression Machine

2025-01-8352To be published on 04/01/2025

Airborne compression ignition engines operating with aviation fuels are a promising option for reducing fuel consumption and increasing the range of hybrid-electric aircraft. However, the consistent ignition of Jet fuels at high-altitude conditions can be challenging. A potential solution to this problem is to ignite the fuel sprays by means of a glow-plug-based ignition assistant (IA) device. The interaction between the IA and the spray, and the subsequent combustion event result in thermal cycles that can significantly affect the IA's durability. Therefore, designing an efficient and durable IA requires detailed understanding of the influence that the IA temperature and insertion depth have on the complex physics of fuel-air mixture ignition and flame propagation. The objective of this study is to design a conjugate heat transfer (CHT) modeling framework that can numerically replicate F-24 Jet fuel spray ignition using a glow-plugbased IA device in a rapid compression machine (RCM

Oruganti, Surya Kaundinya, Lien, Hao-Pin, Torelli, Roberto, Motily, Austen, Lee, Tonghun, Kim, Kenneth, Mayhew, Eric, Kweon, Chol-Bum

Machine Learning Based Lane Detection and Lateral Offset Estimation Model for Vehicle Following Applications

2025-01-8020To be published on 04/01/2025

Precisely understanding the driving environment and determining the vehicle's exact position are crucial for the safe operation of Autonomous Vehicles. In the vehicle following systems that offer higher energy efficiency by precisely following a lead vehicle, the relative position of the ego vehicle to lane center is a key measure to a safe automated speed and steering control. This article presents a novel Enhanced Lane Detection technique with centimeter-level accuracy in estimating the vehicle offset from the lane center using the front-facing camera. Leveraging state-of-the-art computer vision models, the Enhanced Lane Detection technique utilizes YOLO-V8 image segmentation, trained on a diverse real-world driving scenarios dataset, to detect the driving lane. To measure the vehicle lateral offset, our model introduces a novel calibration method using nine reference markers aligned with the vehicle perspective and converts the lane offset from image coordinates to real-world

Karuppiah Loganathan, Nirmal Raja, Poovalappil, Aman, Naber, Jeffrey, Robinette, Darrell, Bahramgiri, Mojtaba

Development of the Tour Split-Cycle Internal Combustion Engine

2025-01-8394To be published on 04/01/2025

The Tour engine is a novel split-cycle internal combustion engine (ICE) that divides the four-stroke Otto cycle of a conventional ICE between two separate cylinders, an intake and compression cylinder and a second expansion and exhaust cylinder, interconnected by an innovative charge transfer mechanism. The engine working fluid, air and fuel, is inducted into the engine and compressed by a dedicated compression cylinder, transferred with minimal pressure loss via an input port to a specifically designed combined spool shuttle transfer mechanism and combustion chamber. It is then ignited and then transferred from the combustion chamber via an exit port to a separate expansion cylinder where it is expanded and exhausted from the engine. The primary advantage of the Tour engine is that it provides the engineering freedom to independently design, control and optimize the compression, combustion, and expansion processes within a slider-crank piston engine. By decoupling the compression

Tour, Oded, Cho, Kukwon, Hofman, Yehoram, Anderson, Bradley, Kemmet, Ryan, Morris, Daniel, Wahl, Michael, Bhanage, Pratik, Sivan, Ehud, Tour, Gilad, Atkinson, Chris, Tour, Hugo

Ignition and Combustion Improvement via Ignition Modulation under Flow Conditions

2025-01-8403To be published on 04/01/2025

In order to reduce the environmental impact of transportation, the adoption of low and zero carbon fuel is needed to reduce the greenhouse gas emissions from engines, both from tailpipe and well-to-wheel perspectives. However, for some of the promising fuels, such as renewable natural gas and ammonia, the relatively low chemical reactivity and laminar flame speed bring challenge to a rapid and efficient combustion process, especially under lean or diluted conditions to suppress NOx emissions, leading to reduced combustion and thermal efficiencies. To tackle the challenge, high in-cylinder turbulence intensity is needed to shorten the combustion duration, together with strong ignition sources to support the initial flame kernel development. In this paper, an ignition energy modulation system is developed to enhance both discharge duration and discharge energy of a spark event to secure the ignition process. Moreover, a rapid compression machine is employed to compress the fuel-air

Jin, Long, Yu, Xiao, Zhou, Qing, Reader, Graham, Li, Liguang, Zheng, Ming

Effective Pt-based N-doped Carbon Nanosphere Electro-catalyst for the Application in PEMFC

2025-01-8551To be published on 04/01/2025

With the growing energy crisis, people urgently need green energy sources to replace fossil ones. As a zero-emission clean energy source, the proton-exchange membrane fuel cell (PEMFC) has received growing attention from researchers due to its broad practical application. However, the large-scale application of PEMFC is currently impeded by their unsatisfying power output and high cost. PEMFC is composed of multiple components, among which the catalyst layer significantly affects the output power and cost of PEMFC. Drastically reducing the amount of platinum in the catalyst layer can bring great benefits to PEMFC, yet causing the large voltage loss associated with enlarged local oxygen molecule transport. Cutting down the platinum content in the catalyst layer can yield substantial cost savings for PEMFC. Developing an efficient catalyst possessing enhanced oxygen reduction reaction (ORR) catalytic performance is conducive to the commercialization of low-Pt proton exchange membrane

Liu, Yuchen, Liu, Xin, Cai, Xin, DU, Aimin, Lin, Rui

High-Performance and Stable Three-Way Catalyst Achieved via Ultrasonic Treatment for Gasoline Vehicle Emission Control

2025-01-8480To be published on 04/01/2025

Three-way catalysts (TWCs) containing significant amounts of precious metals are commonly employed to purify exhaust emissions (CO, NOx, and THC) from gasoline-powered vehicles. A critical factor contributing to TWC degradation is the sintering of these precious metals. Maintaining the appropriate particle size and distribution of the metals is essential for optimal catalyst performance. In this study, palladium (Pd) nanoparticles with a uniform size were synthesized using ethylene glycol as a reductant under ultrasonic conditions, yielding particles in the range of 3 nm to 5 nm. These Pd nanoparticles were subsequently used to prepare three-way catalysts on cordierite substrates supplied by Corning (China) Inc. Chemisorption analysis revealed that the Pd active component in the catalysts prepared via the ultrasonic method exhibited higher dispersion than the state-of-the-art commercial catalysts. The aged catalysts were obtained after 150 hours of aging following the General Motors

Hao, Shijie, Lv, Yanan, Wang, Weidong, Rao, Chao, Wei, Wei, Mao, Bingbin, Chen, Tao, zhao, Huawang

Ammonia-Hydrogen Combustion in a Heavy-Duty Diesel Engine Converted to Spark Ignition Operation

2025-01-8448To be published on 04/01/2025

Ammonia is a carbon-free fuel alternative for the internal combustion engine decarbonization. However, its toxicity and less advantageous combustion characteristics including higher nitrogen-based engine-out emissions have delayed its use in power generation applications. Therefore, the use of a secondary and also carbon-free fuel such as hydrogen was proposed in the literature as a solution to promote and improve ammonia combustion while minimizing any modifications in engine parameters and control strategy that may be required when compared to using conventional hydrocarbon-based fuels. In addition, the higher resistance to autoignition of ammonia can allow operation at higher compression ratios in spark ignition applications, therefore increasing the thermal efficiency. The study presented here used a single-cylinder heavy-duty research engine converted to spark ignition operation to investigate medium load engine operation with ammonia-hydrogen blends in which hydrogen represented

Alvarez, Luis, Saenz Prado, Stefany, Trujillo Grisales, Juan, Dumitrescu, Cosmin

The numerical study of methane flame characteristics in the ammonia/air environment at sub-atmospheric pressure

2025-01-8450To be published on 04/01/2025

The low emission of carbon and minimum level of soot formation in combustion engines and turbines strategy is adopted by many countries to counteract global warming and climate change. The combustion and emission characteristics of methane coflow flame were studied at low pressure and air polluted by ammonia conditions. The results showed that a significant decline in carbon formation was observed when ammonia was boosted, 5-10%. The impact of sub-atmospheric pressure, 90-70 KPa, on COx development was higher than that of NH3 addition, 0-5%, thanks to the lower formation of hydroxymethylium, formaldehyde, and aldehyde radical. The sub-atmospheric pressure had more impact on the reduction of nitric oxide than that of nitrous oxide, and ammonia impact was greater on the increment of nitric oxide than that of nitrous oxide. The maximum reduction and increment in the profile of nitric oxide were observed ~ 42.1% at 5% NH3 and 182% at 80 KPa. The acetylene species was more affected by sub

HINA, ANAM, Akram, M Zuhaib

Biodiesel and Renewable Diesel Blends Oxidation by Diesel Oxidation Catalyst

2025-01-8500To be published on 04/01/2025

Soy-based mono-alkyl esters of long chain fatty acids is the most common biodiesel fuel used in the United States. Other renewable fuels such as renewable diesel (RDE) is also popular, especially in the state of California. All the renewable and alternative fuels are being evaluated for their performance and performance transparency with ultra-low sulfur diesel (ULSD) to be used a substitute to ULSD. Previous research with biodiesel, showed an elevated lightoff temperature on diesel oxidation catalyst (DOC) and worse DOC efficacy in oxidizing fuel blends with fuel blends with more than 20% biodiesel. A similar study was conducted with RDE to gage the performance of the fuel blends of B100 and RDE. The same DOC used in past study was used to evaluate fuel blends of 100% RDE to 40% RDE (B60R40) in decrements of 10%. The performance of the DOC was evaluated on steady-state performance cycle and transient lightoff curve. Similar to the results in past study, the performance of the DOC is

Lakkireddy, Venkata, Weber, Phillip, McCormick, Robert, Howell, Steve

Energy-Efficient Maneuvering of Connected and Automated Vehicles: NEXTCAR Phase II Results

2025-01-8385To be published on 04/01/2025

Onboard sensing and Vehicle-to-Everything (V2X) connectivity enhance a vehicle's situational awareness beyond direct line-of-sight scenarios. A team led by Southwest Research Institute (SwRI) demonstrated 20% energy savings by leveraging these streams on a 2017 Prius Prime as part of the first phase of the ARPA-E-funded NEXTCAR program. When combined with automation, these information streams can not only improve vehicle safety but also enhance energy efficiency further. In the second phase, SwRI demonstrated 30% energy savings over the baseline by leveraging connectivity with higher levels of automation. This paper summarizes the efforts to achieve 30% savings on a 2020 Honda Clarity PHEV. The vehicle was outfitted with the SwRI Ranger automated driving suite for perception and localization. Model-based control schemes with selective interrupt and control (SIC) were used to override stock vehicle controls and actuate the accelerator and brake pedals, and the electric power steering

Bhagdikar, Piyush, Gankov, Stanislav, Sarlashkar, Jayant, Hotz, Scott, Rajakumar Deshpande, Shreshta, Rengarajan, Sankar, Adsule, Kartik, Drallmeier, Joseph, D'Souza, Daniel, Alden, Joshua, Bhattacharjya, Shuvodeep

Effect of Fuels on Compression Ignition Engine Particle Number and Mass Emissions and DPF Filtration Efficiency

2025-01-8502To be published on 04/01/2025

As part of decarbonization, alternative fuels are likely to be used in compression ignition internal combustion engines as a substitute for diesel fuel. There have been many studies on the effect of these alternative fuels on emissions and catalytic aftertreatment systems. Past research has reported lower particulate matter (PM) and higher oxides of nitrogen (NOx) with biofuels. However, there are limited studies on the effect of PM on the performance of diesel particulate filters (DPFs), especially in its effectiveness of PM filtration. PM emissions from four (4) types of fuels and five (5) of their blends, a total of nine fuels, were investigated using PM2.5 mass, soot mass, solid particle number (> 10 nm SPN10 and > 23 nm SPN23)and size distribution (6 nm to 560 nm) measurements at inlet and outlet of a DPF. The PM emissions were measured over a non-road regulatory cycle sequence consisting of five (5) non-road transient cycles (NRTCs) and five (5) non-road steady-state cycles

Lakkireddy, Venkata, Khalek, Imad, Buffaloe, Gina

Research on the Control Strategy of Permanent Magnet Synchronous Motors with Reduced Rotor Stack Length in Hybrid System

2025-01-8563To be published on 04/01/2025

The key issue in the electromagnetic design of permanent magnet synchronous motors is the design of the rotor structure form of the motor. To achieve the goal of reducing the cost of the motor, this paper conducts electromagnetic design, optimal control calibration of the motor, and performance analysis for reducing the rotor lamination structure, and obtains the characteristics of the permanent magnet synchronous motor under this rotor structure. For the permanent magnet synchronous motor with reduced rotor stack length and one less motor temperature sensor, starting from vector control, the conditions for obtaining the maximum electromagnetic torque and the highest rotational speed are derived. Based on these conditions, the vector control strategies for the system operating under different working conditions are designed. At low speeds, the thermal loss of the stator winding is reduced with the maximum torque current ratio to improve the motor efficiency; as the rotational speed of

Jing, Junchao, Zhang, Junzhi, Yu, Pengfei, Liu, Yiqiang, Chen, Yingchao, Dai, Zhengxing

Development of a Test Course Selection Method for Statistically Correct Wind Modeling on US Public Roads

2025-01-8780To be published on 04/01/2025

Traditional automotive aerodynamic development relies on wind tunnel testing and Computation Fluid Dynamics (CFD), where the former provides reliable values to be used for fuel economy calculations, and the latter enables the investigation of the flow features responsible for improvement/degradation of the averaged large-scale performances in terms of aerodynamic coefficients. The abovementioned procedure overlooks a crucial factor: natural wind. The speed of the wind encountered while driving alters the vehicle’s effective yaw angle. Such condition implies that the minimization of the drag coefficient at zero-yaw, commonly performed through wind tunnel testing and CFD simulations, may not yield real-world optimal shapes. While it is possible to employ a wind signal as an input in a wind tunnel, the signal itself must be available beforehand, and such key element is the focus of the present research effort. In this paper, we explain a methodology behind the selection of a statistically

Nucera, Fortunato, Onishi, Yasuyuki, Metka, Matt

Design and Evaluation of a Conceptual Zero-Emission Truck Model Considering Aerodynamic Efﬁciency

2025-01-8784To be published on 04/01/2025

Emerging zero-emission-powertrain concepts for heavy trucks are providing opportunities to re-shape the vehicle for improved aerodynamics, leading to improved energy efficiency and range resulting from reduced drag. A multi-phase project was initiated to investigate the possibility of improving the aerodynamic efficiency of Class 8 trucks with internal-combustion, battery-electric, and hydrogen-fuel-cell powertrains. Early phases included a scaled-model wind-tunnel test that demonstrated the potential for up to 9% drag reduction from simple shape adaptations, with a follow-up CFD study providing guidance towards further optimization. This paper presents wind-tunnel-test results using a high-fidelity 30%-scale model of the final design concept, with comparison to a conventional North American Class 8 truck with a modern aerodynamic package and identical wheelbase. The study included the investigation of the new model along with individual parts such as air dams, underbody panels, grill

Ghorbanishohrat, Faegheh, McAuliffe, Brian, O'Reilly, Harrison

Lattice based Localized Energy Absorber for Improved Vulnerable Road User Performance for a Vehicle

2025-01-8723To be published on 04/01/2025

A passenger vehicle hood is designed to meet Vulnerable Road User (VRU) regulatory requirements and Consumer metric targets. Generally, hood inner design and its reinforcements, along with deformable space available under the hood are the main enablers to meet the Head Impact performance targets. However, cross functional balancing requirements like hood stiffness and packaging space constraints can lead to higher Head Injury Criteria (HIC) scores, particularly when secondary impacts are present. In such cases, a localized energy absorber is utilized to absorb the impact energy to reduce HIC within the target value. The current localized energy absorber solutions include the usage of flexible metal brackets, plastic absorbers etc. which has limited energy absorbing capacity and tuning capability. This paper focuses on usage of a novel 3D printed energy absorbers, based on various kind of lattice structures. These absorbers are either sandwiched between hood inner and the outer or are

Kinila, Vivekananda, Agarwal, Varun, V S, Rajamanickam, Tripathy, Biswajit, Gupta, Vishal

An Investigation of the Inter-Vehicle Distances and Lateral offsets on Aerodynamic Forces and Wake Structures of Vehicles Platooning

2025-01-8769To be published on 04/01/2025

In traffic scenarios, the spacing between vehicles plays a crucial role, as the actions of one vehicle can significantly impact others, particularly with regards to energy conservation. Accordingly, modern vehicles are equipped with inter-vehicle communication systems to maintain specific distances between vehicles. The aerodynamic forces experienced by both leading vehicles (leaders) and following vehicles (followers) are connected to the flow patterns in the wake region of the leaders. Therefore, improving our understanding of the turbulent characteristics associated with vehicles platooning is important. This paper investigates the effects of inter-vehicle distances on the flow structure of two vehicles: a small SUV as the leader and a larger light commercial van as the follower, using a Delayed Detached Eddy Simulation (DDES) CFD technique. The study focuses on three specific inter-vehicle distances: S = 0.28 L, 0.4L, and 0.5L, where S represents the spacing between the two

Mosavati, Maziar, Guzman, Arturo, Lounsberry, Todd, Fadler, Gregory

Numerical Investigation of Gas Diffusion Layer Properties in PEMFC

2025-01-8314To be published on 04/01/2025

This study presents a comprehensive numerical analysis of the characteristics of the gas diffusion layer (GDL) in proton exchange membrane fuel cells (PEMFCs). Fuel cells are devices that generate electricity by reacting hydrogen with oxygen. Hydrogen supplied from a high-pressure tank reacts with oxygen within the fuel cell stack, generating electricity that drives a motor. Given the diverse design requirements for fuel cells, including applications in commercial vehicles and stationary systems, efficient material design through numerical models and simulations is indispensable. The GDL, composed of carbon fibers and resin, functions as a cushion under cell compression and facilitates the transport of electrons, heat, gas, and water. Its microstructure significantly influences these properties, making precise design crucial. In this study, we automated the material exploration by varying parameters such as the diameter and quantity of carbon fibers, as well as the amount and

Ota, Yuki, Dobashi, Toshiyuki, Nomura, Kumiko, Hattori, Takuya, Maekawa, Ryosuke

Development of Ceramic Humidity Regulator (CHR) Using Honeycomb Type PTC Heater to Improve Electric Vehicle Driving Range in Winter

2025-01-8177To be published on 04/01/2025

With Rapid growth of Electric Vehicles (EVs) in the market, challenges such as driving range, charging infrastructure, and reducing charging time needs to be addressed. Unlike traditional Internal combustion vehicles, EVs have limited heating sources and primarily uses electricity from the running battery, which reduces driving range. Additionally, during winter operation, it is necessary to prevent window fogging to ensure better visibility, which requires introducing cold outside air into the cabin. This significantly increases the power consumption for heating and the driving range can be reduced to half of the normal range. This study introduces the Ceramic Humidity Regulator (CHR), a compact and energy-efficient device developed to address driving range improvement. The CHR uses a desiccant system to dehumidify the cabin, which can prevent window fogging without introducing cold outside air, thereby reducing heating power consumption. A desiccant system typically consists of two

Hamada, Takafumi, Shinoda, Narimasa, Konno, Yoshiki, Ihara, Yukio, Ito, Masaki

A Novel Hybrid Approach for Segmenting Driver Based on their Driving Style

2025-01-8205To be published on 04/01/2025

Drivers present a diverse landscape with their distinct personalities, preferences, and driving habits influenced by many factors. While drivers exhibit a wide range of behaviors, identifiable patterns in driving styles enable the classification of drivers into discrete segments. Discrete segmentation provides a practical and effective way to categorize and address the differences in driving style. The segmentation approach offers many benefits, including simplification, measurement, proven methodology, customization, and safety. Numerous studies have investigated driving style classification using real-world vehicle data. These studies employed various methods to identify and categorize distinct driving patterns, including naturalist differences in driving and field operational tests. This paper presents a novel hybrid approach for segmenting driver behavior based on their driving patterns. We leverage vehicle acceleration data to create granular driver segments by combining event

Chavan, Shakti Pradeep, Chinnam, Ratna Babu

Comparative Analysis of Mass Estimation Methods for Heavy-Duty Vehicles under Varying Payload Conditions

2025-01-8209To be published on 04/01/2025

Accurate mass estimation is essential for commercial heavy-duty vehicles (HDVs), as fluctuating payloads significantly impact energy consumption. Precise vehicle mass estimates enhance the accuracy of energy consumption models, leading to more effective energy management systems and performance optimization strategies. For example, improved energy estimates can lead to more optimized routing and refueling schedules, improving operational efficiency and reducing costs. In the context of electrification, accurate mass estimates can inform battery sizing, range predictions, and charging requirements, enabling optimized charge scheduling and seamless integration of electric HDVs into existing operations. While direct mass measurements may be obtained through external weight-in-motion or specialized onboard weighing systems, this paper focuses on methods that use data from Controller Area Network (CAN) systems for alternative real-time predictions. The challenge lies in identifying a method

Jayaprakash, Bharat, Eagon, Matthew, Fakhimi, Setayesh, Kotz, Andrew, Northrop, William

Spectral Estimation to Quantify Road/Track Surface Degradation

2025-01-8252To be published on 04/01/2025

Track testing methods are utilized in the automotive industry for emissions and fuel economy certification. These track tests are performed on smooth road surfaces which deteriorate over time due to wear and weather effects, hence warranting regular track repaves. The study focuses on the impact of repaving on track quality and surface degradation due to weather effects. 1D surface profiles and 2D surface images at different spatial frequencies were measured at different times over a span of two years using various devices to study the repave and degradation effects. Data from coastdown tests was also collected over a span of two years and is used to demonstrate the impact of track degradation and repaving on road load characterization parameters that are used for vehicle certification tests. Kernel density estimation and non-parametric spectral estimation methods are used to visualize the characteristic features of the track at different times. In the pre-processing stage, outliers

Singh, Yuvraj, Jayakumar, Adithya, Rizzoni, Giorgio

A Comparative Analysis of Acceleration and Deceleration Profiles for Aggressive Driving Styles and Fuel Economy Test Cycles

2025-01-8605To be published on 04/01/2025

Efficient and sustainable transportation in urban environments depends on understanding driving behaviors, and their implications. This study explores into the distinction between aggressive and non-aggressive driving patterns, leveraging an on-road driving dataset provided by an automotive company. By contrasting this data with established Fuel Economy cycles from United States Environmental Protection Agency (EPA) and employing curve-fitting techniques, the research not only reveals driving patterns but also predicts potential behaviors in unfamiliar scenarios. Results show significantly different acceleration profile patterns between different driving behaviors which has serious impact in fuel economy and environmental wellness. The findings highlights the environmental impact of driving behaviors, paving the way for environmentally responsible policy recommendations and sustainable driving practices

Padmanaban, Gandhimathi, Feng, Fred, Dai, Edward, Saini, Ankit, Hu, Guopeng, Zhao, Yanan

Smart Boosting: A Control Strategy for Optimized Energy Management with Boost Converter in Hybrid Electric Vehicles

2025-01-8580To be published on 04/01/2025

In hybrid electric vehicles (HEVs), optimizing energy management and reducing system losses are critical for enhancing overall efficiency and performance. This paper presents a novel control strategy for the boost converter in hybrid electric vehicles (HEVs), aimed at minimizing energy losses and optimizing performance by modulating to a higher boost converter voltage only when necessary. Traditional approaches to boost converter control often lead to unnecessary energy consumption by maintaining higher voltage levels even when not required. In contrast, the proposed strategy dynamically adjusts the converter's operation based on real-time vehicle demands, such as driver input, Engine Start-Stop (ESS) events, Active Electric Motor Damping (AEMD), entry and exit transitions for Engine Fuel Cut-Off (DFCO), Noise-Vibration-Harshness (NVH) events like lash-zone crossing and other specific operational conditions. The control strategy leverages predictive algorithms and real-time monitoring

Basutkar, Ameya, Berger, Daniel, Huo, Shichao, Sullivan, Claire, Tischendorf, Christoph

Evaluation of Different Powertrain Topologies for a Premium Plug-in Hybrid Electric Vehicle

2025-01-8531To be published on 04/01/2025

Plug-in hybrid electric vehicles combine the benefits of both battery electric and internal combustion engine drivetrains. There are multiple possibilities for hybrid configurations, each with its own advantages and disadvantages. In this study, two newly developed traction electric machines were employed alongside a gasoline engine in various hybrid configurations. These configurations, ranging from P1 to P4 and their combinations, were evaluated in terms of vehicle performance, energy consumption, and emissions. The impact of battery capacity was also examined. With a larger battery providing higher discharge power, the electric acceleration time significantly decreases from around 8.6 seconds to approximately 5.2 seconds as the battery capacity increases from 20 kWh to 40 kWh in configurations featuring two traction electric machines. In hybrid mode, the reduction in acceleration time is less pronounced, with a decrease of around 0.7 seconds compared to the configuration with a 20

Nguyen, Duc-Khanh, Tokat, Alexandra, Kristoffersson, Annika, Olsson, Jan-Ola

On the potentially misleading evaluation of CO2 emissions for hybrid-electric vehicles

2025-01-8537To be published on 04/01/2025

The adoption of hybrid electric vehicles (HEVs) is becoming more popular during the last few years due to government incentives and favourable legislation both for automotive companies and final users. This type of vehicle claims very low carbon dioxide emissions while eliminating the range anxiety associated with battery electric vehicles thanks to the on-board range extender being able to recharge the battery throughout the journey. Unfortunately, the low emissions values are more representative of the particular mathematical model implemented by the legislation than the measured real driving emissions. Specifically, the legislation does not take into account the CO2 embedded in production of the batteries or of the electrical energy stored in it. This work analyses these aspects by means of a numerical model of the BMW i3 94Ah vehicle. The results obtained are collected from simulations conducted over the Worldwide harmonized Light vehicles Test Cycle (WLTC) by using the commercial

Turner, James, Vorraro, Giovanni

Parameter identificaton of solid oxide fuel cell using teaching-learning based collective intelligence

2025-01-8545To be published on 04/01/2025

The accurate extraction of internal operating parameters associated with multi-physicochemical processes forms the basis for precise modelling of solid oxide fuel cells (SOFCs), which serves as the foundation for predicting performance degradation and estimating the lifespan of SOFCs. In this work, a novel integration of the teaching-learning based algorithm (TLBO) and collective intelligence (CI), referred as the teaching-learning based collective intelligence algorithm (TLBO-CI), is introduced. This algorithm utilizes diverse characteristic patterns, including current-voltage (I-V) curves and electrochemical impedance spectroscopies (EIS), to enhance the overall identification of degardation process.Experimental data was gathered from a 3-cell SOFC short stack during a 640-hour durability test. The proposed parameter identification algorithm employs a collective intelligence framework, wherein sub-identifiers are based on particle swarm optimization (PSO) and individually tasked with

Wang, Zheyu, Shen, Yitao, Sun, AoTong, Han, Beibei, Ma, Xiao, Shuai, Shijin

Model-Based Evaluation of Hybrid Powertrains for a Light Duty Pickup Truck Application

2025-01-8532To be published on 04/01/2025

The ever-growing push for reducing GHG and NOx emissions has been challenging vehicle manufacturers globally. In the USA, multi-pollutant emissions standards finalized recently by EPA, for model years 2027 and later aim to reduce the CO2 emissions by 56% and 44%, respectively, for light and medium duty vehicles by 2032. The NMOG+ and NOx are also required to be reduced by 60 – 76% by 2032 from 2026 levels. Europe is also aiming to reduce CO2 emissions by 55% by 2030 from 1990 levels and 100% by 2035. To achieve such low levels of CO2 emissions, especially in the near-term scenario of limited EV sales, hybridization of conventional powertrains has found renewed interest. While hybrid powertrains add complexity, if optimized well for the application, they can offer best tradeoff between upfront cost, range, payload, performance, emissions and off-ambient operation. This study investigates the benefits and challenges of various hybrid architectures suitable for a pickup truck application

Fnu, Dhanraj, Correia Garcia, Bruno, Paul, Sumit, Joshi, Satyum, Franke, Michael

A Loss-Based Approach to Controlling the Optimum Power Request of an Energy Provider Such as a Fuel Cell

2025-01-8548To be published on 04/01/2025

Optimizing energy providers like fuel cells and engines involves considering various factors, constraints, and requirements. These include NVH (Noise, Vibration, and Harshness), durability, operating point efficiency, and customer expectations. Different energy providers prioritize these factors differently. For instance, NVH is crucial for engines due to customer expectations regarding start-up, sound, and power delivery based on accelerator input. In contrast, fuel cells face fewer constraints but must consider noise from electrical AC compressors and other devices, especially at lower vehicle speeds. However, operating point efficiency and durability are paramount for fuel cells, as they are expected to last as long as engines in conventional vehicles sold today. This paper proposes a holistic approach that begins at the vehicle or powertrain architecture level and designs an operating strategy that integrates all the aforementioned factors to enhance the operation of a fuel cell

Patel, Nadirsh, Kudupley, Harshal

Powertrain components aging model selection for energy efficient vehicles: selection strategy and challenges

2025-01-8541To be published on 04/01/2025

The long-term performance of powertrain components in energy-efficient vehicles, particularly in Class 8 heavy-duty applications, is crucial for sustaining energy efficiency. However, these components degrade over time, leading to reduced performance and highlighting the need for appropriate aging models to estimate the impact of aging. This study aims to identify and select appropriate aging models for two critical powertrain components: battery and electric machine. Through a comprehensive literature review, the primary aging processes, key influencing factors, and available aging models for these components are identified. A selection matrix is established, considering model complexity, accuracy, and the volume of data required to maintain the desired precision for the powertrain component models. Based on the selection matrix, an appropriate model is chosen for the vehicle’s battery. This model was selected for its ability to effectively capture the aging process and estimate

Rownak, Md Ragib, Hanif, Athar, Ahmed, Qadeer, Fahim, Muhammad Qaisar, Anwar, Hamza, Li, Hui, Le, Dat, Nelson, Matthew

Accelerated reactive force field molecular dynamics simulation on the carbon diffusion process in Ni/YSZ anode of SOFCs with collective variable-driven hyperdynamics

2025-01-8554To be published on 04/01/2025

Due to advantages such as high efficiency, low emissions, and fuel flexibility, solid oxide fuel cells (SOFCs) have gained attention as promising power devices for automotive applications. The nickel/yttria-stabilized zirconia (Ni/YSZ) material can catalyze chemical and electrochemical reactions of carbon-containing fuels and is one of the most widely utilized anode materials of the SOFC. However, the direct use of carbon-containing fuels can lead to carbon deposition on Ni/YSZ anode, affecting the performance and reliability of vehicle SOFC systems. The diffusion of carbon atoms in nickel influences the carbon deposition process and requires further investigation. In this study, a reactive force field molecular dynamics (ReaxFF-MD) model containing carbon atoms and Ni/YSZ crystal structure is established. The operating temperature of automotive SOFCs is 800-1200 K, which leads to a low frequency of diffusion events in the ReaxFF-MD model, resulting in high computational costs

Du, Haoyu, Zhang, Kaiqi, Xiao, Ma, Zhang, Xiaoqing, Shuai, Shijin

Analysis of the design space for battery and fuel cell powered electric trucks

2025-01-8600To be published on 04/01/2025

A diverse set of solutions will likely be needed to decarbonize the commercial truck sector in US. Battery powered vehicles definitely has a predominant role in this, but there are several areas where fuel cell trucks are more advantageous for the consumer. This study examines several prominent medium and heavy duty applications, designed for different driving range requirements to identify the design space where battery and fuel cell trucks are attractive. The impact of purchase price, fuel cost, vehicle usage are also considered in this analysis. Since future costs cannot be accurately predicted, this study includes parametric sweeps with certain high and low values to examine the uncertainty of the observations. This work examines the top 10 truck classes based on vehicle population, fuel usage and driving distances. It also considers some of the bus applications such as coach, transit and school buses. The vehicle usage information taken from VIUS as well as inputs from the 21CTP

Vijayagopal, Ram, Birky, Alicia

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