Topic Editors

CMT-Clean Mobility & Thermofluids, Universitat Politècnica de València, Valencia, Spain
CMT-Motores Térmicos, Universitat Politécnica de València, Valencia, Spain

Decarbonised Powertrains and Emission Control in Transportation

Abstract submission deadline
closed (31 March 2023)
Manuscript submission deadline
closed (30 June 2023)
Viewed by
19317

Topic Information

Dear Colleagues,

In an effort to reduce powertrain systems’ impact on the environment, a significant reduction of CO2 emissions is required in upcoming years, with the aim of a 15% reduction by 2025 and 37.5% reduction by 2030. In this sense, two main strategies are being pursued. On one hand, powertrain electrification, including purely electrical (battery or fuel-cell based) as well as hybrid powertrains, is currently seen as the main path for light- and medium-duty vehicles. On the other hand, advanced combustion concepts and low- or zero-carbon fuels are being considered for heavier sectors, including long-haul trucks, aircraft and maritime applications.

Each strategy has its own challenges. Battery-electric powertrain development is focused on increasing power density and durability while increasing safety, particularly mitigating the risk of thermal runaway events. In the case of fuel-cell systems, the aims are to reduce cost through reduced Pt content in the catalyst and new materials for the bipolar plates, and also to improve their transient response and mitigate the subsequent degradation mechanisms. For hybrid-electric vehicles, which generally use a gasoline spark-ignition engine, one of the main challenges is related to the aftertreatment deactivation linked to the continuous starting and stopping of the thermal engine, which can lead the aftertreatment to fall below the activation temperature by the time the engine is restarted. Moreover, more frequent operation under near cold-start conditions inside the cylinders can increase the production of unburned hydrocarbons and particulate emissions.

In the case of advanced combustion concepts and fuels, the two main concerns are as follows: on one hand, the new combustion setup must be optimized in order to provide the maximum possible emission control on the combustion side. On the other hand, the composition of the exhaust gases can be dramatically changed, affecting the boundaries for the operation of the aftertreatment system needed to abate the gaseous emissions. For instance, new engine concepts based on hydrogen or ammonia combustion would produce aftertreatment gases mainly composed of nitrogen, water, oxygen, NOx and NH3. Instead, other concepts such as oxy-fuel combustion would not produce NOx if all N2 is removed, but HC/CO management would be needed if novel carbon-based (such as e-fuels) were used. In both cases, new a proposals aimed at reducing these emissions for new exhaust-gas compositions (including a highly humid environment) may be required.

This Special Issue encourages works from both industry and academia that focus on the analysis of pollutant emissions formation and control with regard to decarbonized powertrain platforms. Potential topics include (but are not limited to):

  • Novel materials for battery and fuel cell electric vehicles.
  • Analysis of thermal runaway events for battery-electric powertrains.
  • Fuel-cell degradation mechanisms and their mitigation.
  • Development and emissions impact of novel combustion strategies.
  • Combustion and emissions characterization with alternative fuels (biofuels; e-fuels; H2; NH3, etc.)
  • Powertrain architecture based on oxy-fuel combustion concepts.
  • Hybrid powertrain emissions in driving cycles.
  • Emissions characterization in engine cold-start operation.
  • Characterization of exhaust aftertreatment systems.
  • New modeling approaches in powertrain applications: from system level to component level.
  • OBD and control strategies.
  • New catalysts formulations for emission control.
  • Health and environmental impact of vehicle emissions.
  • Life-cycle analysis (LCA) and total ownership cost (TCO) for decarbonized powertrains.

Dr. Pedro Piqueras
Dr. Joaquin de la Morena
Topic Editors

Keywords

  • decarbonized powertrains
  • fuel cells
  • batteries
  • hybridization
  • emission control
  • exhaust aftertreatment systems
  • catalysts formulation
  • advanced combustion
  • low-carbon fuels
  • on-board diagnostics

Participating Journals

Journal Name Impact Factor CiteScore Launched Year First Decision (median) APC
Applied Sciences
applsci
2.5 5.3 2011 17.8 Days CHF 2400
Energies
energies
3.0 6.2 2008 17.5 Days CHF 2600
Vehicles
vehicles
2.4 4.1 2019 24.7 Days CHF 1600
Catalysts
catalysts
3.8 6.8 2011 12.9 Days CHF 2200
Sensors
sensors
3.4 7.3 2001 16.8 Days CHF 2600

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Published Papers (6 papers)

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16 pages, 11862 KiB  
Article
Numerical Study on Sensitivity of Turbofan Engine Performance to Blade Count of Centrifugal Compressor Impeller
by Arkadiusz Bednarz, Kirill Kabalyk, Robert Jakubowski and Rafał Bartłomowicz
Energies 2023, 16(14), 5251; https://doi.org/10.3390/en16145251 - 8 Jul 2023
Cited by 3 | Viewed by 1742
Abstract
The aim of this publication was to investigate the effects the blade count of a high-pressure centrifugal compressor’s impeller has on the performance of the DGEN 380 turbine engine at take-off. The study began with the development of a zero-dimensional thermo-fluid model of [...] Read more.
The aim of this publication was to investigate the effects the blade count of a high-pressure centrifugal compressor’s impeller has on the performance of the DGEN 380 turbine engine at take-off. The study began with the development of a zero-dimensional thermo-fluid model of the engine. The model was matched with experimental data from the WESTT CS/BV virtual test bench for the baseline count and then implemented to analyse the engine behaviour at alternative counts. The corresponding changes in the compressor pressure ratio and efficiency were modelled in a commercial 3D CFD software and transferred to the zero-dimensional model with proper scaling. The results proved that the baseline design lied in the optimal range of thrust-specific fuel consumption. The increase in the blade count led to a crisis of the aerodynamic loading at the splitters, so that no further rise in the pressure ratio could be achieved. The results of the study could be implemented by mechanical engineers while solving the tasks of the maintenance and modernisation of gas turbines with radial compressors. Full article
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20 pages, 3595 KiB  
Article
End-of-Life Impact on the Cradle-to-Grave LCA of Light-Duty Commercial Vehicles in Europe
by Antonella Accardo, Giovanni Dotelli, Federico Miretti and Ezio Spessa
Appl. Sci. 2023, 13(3), 1494; https://doi.org/10.3390/app13031494 - 23 Jan 2023
Cited by 7 | Viewed by 3693
Abstract
A cradle-to-grave life cycle assessment focused on end-of-life (EoL) was conducted in this study for three configurations of a light-duty commercial vehicle (LDCV): diesel, compressed natural gas (CNG), and battery electric vehicle (BEV). The aim is to investigate the impact of recycling under [...] Read more.
A cradle-to-grave life cycle assessment focused on end-of-life (EoL) was conducted in this study for three configurations of a light-duty commercial vehicle (LDCV): diesel, compressed natural gas (CNG), and battery electric vehicle (BEV). The aim is to investigate the impact of recycling under two EoL scenarios with different allocation methods. The first is based on the traditional avoided burden method, while the second is based on the circular footprint formula (CFF) developed by the European Commission. For each configuration, a detailed multilevel waste management scheme was developed in compliance with the 2000/53/CE directive and ISO22628 standard. The results showed that the global warming potential (GWP) impact under the CFF method is significantly greater when compared to the avoided burden method because of the A-parameter, which allocates the burdens and benefits between the two connected product systems. Furthermore, in all configurations and scenarios, the benefits due to the avoided production of virgin materials compensate for the recycling burdens within GWP impact. The main drivers of GWP reduction are steel recycling for all of the considered LDCVs, platinum, palladium, and rhodium recycling for the diesel and CNG configurations, and Li-ion battery recycling for the BEV configuration. Finally, the EoL stage significantly reduces the environmental impact of those categories other than GWP. Full article
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18 pages, 3985 KiB  
Article
Characteristics of Real-World Gaseous Emissions from Construction Machinery
by Dong In Lee, Junhong Park, Myunghwan Shin, Jongtae Lee and Sangki Park
Energies 2022, 15(24), 9543; https://doi.org/10.3390/en15249543 - 15 Dec 2022
Cited by 4 | Viewed by 1936
Abstract
In Korea’s air pollutant inventory, construction machinery is a major emission source in the non-road sector. Since 2004, the Korean government has introduced and reinforced emission regulations to reduce the air pollutants emitted from their diesel engines. Since the engine dynamometer test method [...] Read more.
In Korea’s air pollutant inventory, construction machinery is a major emission source in the non-road sector. Since 2004, the Korean government has introduced and reinforced emission regulations to reduce the air pollutants emitted from their diesel engines. Since the engine dynamometer test method used in emission regulations has limitations in reflecting emission characteristics under the diverse working conditions of construction machinery, it is necessary to examine the effectiveness of emission regulations and the validity of the emission factors applied as inputs to the air pollutants inventory. This could be done by evaluating engine operation and emission characteristics under real-world working conditions. In this study, 14 units were selected among the excavators, wheel loaders, and forklifts that represent approximately 90% of the registered construction machines in Korea. They were equipped with a portable emission measurement system (PEMS) to measure gaseous emissions and collect engine data under various real-world working conditions. With the reinforcement of emission regulations for the construction machinery from K-tier3 to K-tier4 in Korea, exhaust after-treatment technologies, such as selective catalytic reduction and diesel oxidation catalyst, were applied. Real world NOx was reduced by approximately 83%, and THC 77% and CO by 73%, respectively. Real world NOx + THC of the K-tier3 machines exceeded the laboratory emission limit, but the K-tier4 machines considerably improved, 20% for excavator (124 kW), 61% for excavator (90 kW), 90% for wheel loader (202 kW) and 21% for Fork-lift (55 kW), despite some differences. The emission factors applied to the air pollutant inventory have been developed using the engine dynamometer test method, but they were considerably underestimated compared with emissions under real-world working conditions. The difference was even larger for the K-tier4 machines. In this study, the possibility of developing emission factor equations that use the engine load factor as a parameter was confirmed by using the engine work 1 g/kW·h segment moving averaging window (MAW) method. Full article
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19 pages, 5166 KiB  
Article
Assessment of Variable Geometry Orifice Compressor Technology Impact in a New Generation of Compression Ignition Powertrains at Low-End and Transient Operation
by José Ramón Serrano, Héctor Climent, Alejandro Gomez-Vilanova, Aditya Darbhamalla and Stéphane Guilain
Appl. Sci. 2022, 12(24), 12869; https://doi.org/10.3390/app122412869 - 14 Dec 2022
Viewed by 1710
Abstract
Surge is a phenomenon that limits the operating range of the compressor at low engine speeds and high boost pressure in turbocharged powertrains. This article assesses two prototype turbochargers of variable geometry orifice (VGO) which compensate for the limitation of the boost pressure [...] Read more.
Surge is a phenomenon that limits the operating range of the compressor at low engine speeds and high boost pressure in turbocharged powertrains. This article assesses two prototype turbochargers of variable geometry orifice (VGO) which compensate for the limitation of the boost pressure at low engine speeds. The VGO prototypes modify the inlet compressor section, extending the compressor characteristic map into lower mass flows (surge limit region). The VGO turbochargers analyzed are also both equipped with variable geometry turbine (VGT) technology. The experiments focus on low-end torque operation ranges in steady and transient engine running conditions. The experimental results are used to validate a 1D physical model. From the modelling perspective, a comprehensive study of the VGO-VGT prototypes is assessed. Results reveal the benefits of VGO technology in terms of attaining higher boost pressure, improved compressor efficiency, and overall engine performance at low engine speeds. Full article
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28 pages, 3816 KiB  
Review
Off-Road Construction and Agricultural Equipment Electrification: Review, Challenges, and Opportunities
by Fuad Un-Noor, Guoyuan Wu, Harikishan Perugu, Sonya Collier, Seungju Yoon, Mathew Barth and Kanok Boriboonsomsin
Vehicles 2022, 4(3), 780-807; https://doi.org/10.3390/vehicles4030044 - 6 Aug 2022
Cited by 18 | Viewed by 7413
Abstract
Though the current wave of electric vehicles is transforming the on-road passenger and commercial vehicle fleets, similar attempts in the off-road equipment sector appear to be lacking. Because of the diverse equipment categories and varied applications, electrifying off-road equipment requires significant research and [...] Read more.
Though the current wave of electric vehicles is transforming the on-road passenger and commercial vehicle fleets, similar attempts in the off-road equipment sector appear to be lacking. Because of the diverse equipment categories and varied applications, electrifying off-road equipment requires significant research and development. A successful electrification of such equipment can offer an array of benefits, including reduced air and noise pollution, higher energy efficiency, and increased productivity. This paper provides a review of the current state of technology in off-road equipment electrification, with a focus on the equipment used in construction and agricultural applications. The paper also discusses advantages of, and challenges associated with, electrifying off-road construction and agricultural equipment. In addition, potential solutions for overcoming these challenges as well as opportunities to facilitate the electrification of off-road construction and agricultural equipment are identified. Full article
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17 pages, 12917 KiB  
Article
Numerical Evaluation in a Scaled Rotor-Less Nozzle Vaned Radial Turbine Model under Variable Geometry Conditions
by José Ramón Serrano, Andrés Omar Tiseira, Juan Antonio López-Carrillo and Natalia Hervás-Gómez
Appl. Sci. 2022, 12(14), 7254; https://doi.org/10.3390/app12147254 - 19 Jul 2022
Cited by 2 | Viewed by 1641
Abstract
The widespread trend of pursuing higher efficiencies in radial turbochargers led to the prompting of this work. A 3D-printed model of the static parts of a radial variable geometry turbine, the vaned nozzle, and the volute, was developed. This model was up-scaled from [...] Read more.
The widespread trend of pursuing higher efficiencies in radial turbochargers led to the prompting of this work. A 3D-printed model of the static parts of a radial variable geometry turbine, the vaned nozzle, and the volute, was developed. This model was up-scaled from the actual reference turbine to place sensors and characterize the flow around the nozzle vanes, including the tip gap. In this study, a computational model of the scaled-up turbine was carried out to verify the results in two ways. For this model, firstly compared with an already validated CFD turbine model of the real device (which includes a rotor), its operating range was extended to different nozzle positions, and we checked the issues with rotor–stator interactions as well as the influence of elements such as the screws of the turbine stator. After showing results for different nozzle openings, another purpose of the study was to check the effect of varying the clearance over the tip of the stator vanes on the tip leakage flow since the 3D-printed model has variable gap height configurations. Full article
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