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A Methodology for Monitoring Real-World CO2 Emissions Compliance in Passenger Vehicles

Aristotle University of Thessaloniki-Nikiforos Zacharof, Stylianos Doulgeris, Ioannis Myrsinias, Zisimos Toumasatos, Athanasios Dimaratos, Zissis Samaras
European Commission Joint Research-Georgios Fontaras
  • Technical Paper
  • 2020-37-0034
To be published on 2020-06-23 by SAE International in United States
The road transport CO2 emissions reduction scheme in the European Union foresees mandatory targets for passenger vehicles. However, several studies have shown that there is a divergence between official and real-world values that it could be up to 40% in the NEDC. The introduction of the WLTP was expected to curb this divergence, but it is uncertain whether it can fully address the problem. In order to address this issue, future legislation aims at monitoring on-road fuel consumption and subsequently CO2 emissions by utilizing on-board fuel consumption meters. The current study investigates a monitoring approach that obtains and normalizes on-road vehicle operation data and estimate CO2 emissions through vehicle simulation. The first step is to create the vehicle’s engine fuel consumption map, based on laboratory vehicle measurements in order to use it as reference data. Subsequently, a methodology is developed to produce the vehicle’s engine map from signals retrieved through the OBD port in order to emulate data availability under a monitoring scheme. The methodology to derive the vehicle’s engine fuel consumption map includes an…
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A Novel Option for Direct Waste Heat Recovery From Exhaust Gases of Internal Combustion Engines

Universita degli Studi dell Aquila-Davide Di Battista, Roberto Cipollone PhD, Roberto Carapellucci PhD
  • Technical Paper
  • 2020-37-0004
To be published on 2020-06-23 by SAE International in United States
Among the different opportunities to save fuel and reduce Co2 emissions from internal combustion engines, great attention has been done on the waste heat recovery: the energy wasted is, in fact, almost two thirds of the energy input and even a partial recovery into mechanical energy is really promising . Usually, thermal energy recovery has been referred to a direct heat recovery (furtherly expanding the gases expelled by the engine thanks to their high pressure and temperature) or an indirect one (using the thermal energy of the exhaust gases – or of any other thermal streams discharged into the atmosphere – as upper source of a conversion power unit which favour a thermodynamic cycle of a working fluid ). Limiting the attention to the exhaust gases, a novel opportunity can be represented by directly exploiting the residual pressure and temperature of the flue gases through an Inverted Brayton cycle (IBC), in which the gases are expanded at a pressure below the environmental one, cooled down and then recompressed to the environmental pressure. Considering the thermodynamic…
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Fuel Consumption and Emission Reduction for Hybrid Electric Vehicles with electrically heated Catalyst

TU Dresden-Frank Atzler
TU Muenchen-Georg Wachtmeister
  • Technical Paper
  • 2020-37-0017
To be published on 2020-06-23 by SAE International in United States
Hybridization is a promising way to further reduce the CO2 emissions of passenger vehicles. However, high engine efficiencies and the reduction of engine load, due to torque assist by an electric motor, cause a decrease of exhaust gas temperature levels. This leads to an increased time to light-off of the catalysts resulting in an overall lower efficiency of the exhaust aftertreatment system. Especially in low load driving conditions, at cold ambient temperatures and on short distance drives, the tailpipe pollutant emissions are severely impacted by these low efficiency levels. To ensure lowest emissions at all driving conditions, catalyst heating methods must be used. In conventional vehicles internal combustion engine measures, e.g. late combustion can be applied. A hybrid system with an electrically heated catalyst enables further methods such as the increase of engine load, the so-called load point shifting by the electric motor or using the energy from the battery for electric catalyst heating. Since these methods result either directly or indirectly in additional fuel consumption there is a conflict of objectives between a fast…
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Simplified Cost-effective Aftertreatment System for Electrified Diesel Applications

Exothermia SA-Dimitrios Karamitros, Christos Avgerinos, Stavros Skarlis, Grigorios Koltsakis
GM Global Propulsion System-Giuseppe Previtero, Fransesco Bechis
  • Technical Paper
  • 2020-37-0023
To be published on 2020-06-23 by SAE International in United States
The Diesel powertrain remains an important CO2 reduction technology in specific market segments due to its inherent thermodynamic combustion efficiency advantages. Diesel powertrain hybridization can bring further potential for CO2 emissions reduction. However, the associated reduction in the exhaust gas temperature may negatively impact the performance of the exhaust aftertreatment (EAT) system and challenge the abatement of other emissions, especially NOx. Considering that active urea-SCR systems may be required to ensure compliance with the legislative limits, the total cost of the hybrid Diesel powertrain is expected to increase even more, therefore making it less commercially attractive. We present a model-based analysis of a 48V Diesel mild hybrid electric vehicle (MHEV) which is combined with an exhaust aftertreatment (EAT) system using Lean-NOx trap (LNT) technology. The overall de-NOx performance is further enhanced with the addition of passive SCR catalysts to benefit from the on-board ammonia formation during rich combustion events. Since the modeling framework is fully physico-chemically informed, it allows the investigation of various topologies, catalyst geometrical and chemical properties. Moreover, the model includes a simplified…
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Assessment of the Potential of Power to Gas Fuels for Replacement of Fossile Fuels in Switzerland

EMPA-Panayotis Dimopoulos Eggenschwiler, Florian Kiefer, Karin Schröter, Christian Bach
  • Technical Paper
  • 2020-37-0027
To be published on 2020-06-23 by SAE International in United States
In Switzerland, road traffic is responsible for one third of greenhouse gas emissions respectively 40% of the CO2 emissions and therefore accounts for the largest single share of all sectors. These emissions have even increased slightly since 1990 (from 15.5 to 16.2 million tCO2). Private individual road transport achieves a mileage of approximatively 91.0 billion pkm (person-kilometer) and 17.2 billion tkm (tons-kilometer) per year. Therefore, 3.3 billion liters of gasoline and 3.2 billion liters of diesel are used, resulting in 16.2 million tCO2 emissions in total. Thereof, 10.2 million tons of CO2 are emitted by passenger cars and 1.7 million tons by trucks, the two most important means of transport concerning CO2 emissions. The rest is produced by vans, buses, motorcycles, railways and shipping, national air traffic and fuel tourism. The passenger cars are the most relevant application in terms of CO2 emissions with a share of 63% of the road vehicle CO2 emissions. To comply with the 95 g/km target, low CO2 vehicles have to be introduced. In the following, the number of such…
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Energy Management for Electric Vehicle Application: Energy Demand for Cabin Comfort

FCA Italy S.p.A.-Antonio Tarzia
  • Technical Paper
  • 2020-37-0031
To be published on 2020-06-23 by SAE International in United States
The rapid development of CO2 reduction policies pushes an equivalent effort by the OEM to design and produce Battery Electric Vehicles (BEV) in order to lower the global CO2 emission of its fleet. The main effort has been done primarily to the electric traction architecture (electric traction motor and battery energy storage). Anyway, the BEV autonomy range is still a weak point and this is even more critical when the customer operates the air conditioning system to reach and maintain the cabin comfort. The aim of this work is to present how the cabin design have to evolve in order to allow the reduction of the energy demand by the Air conditioning system allowing the vehicle to increase the autonomy range.
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On-Board Post-Combustion CO2 Capture in Light-Duty and Heavy-Duty transport

Politecnico di Milano-Davide Bonalumi, Stefano Campanari
  • Technical Paper
  • 2020-37-0012
To be published on 2020-06-23 by SAE International in United States
The European Union set the CO2 emission limit in the transport sector that will decrease in the next years. The purpose of this work is to assess through technical analysis, a system that captures part of the CO2 from the exhaust gases of duty vehicles. Two distinct categories of vehicles are considered, those with a mass lower than 3.5 tons and those with a higher mass. For the light-duty category, the analysis is developed estimating the consumptions and emissions based on the WLTP homologation cycle by means of the software Excel. For the heavy-duty category, the consumptions and the emissions are determined by means of the software specifically developed by the European Union for heavy-duty vehicles named VECTO (Vehicle Energy Consumption calculation Tool). From a literature review, different technologies are considered. The most suitable technology is selected. A possible way is based on the adsorption through the metal-organic framework (MOF). A dedicated review to select the most promising material indicates which can assure the best performance. The performances are evaluated based on the features of…
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Assessing the Engine-Out Pollutant Emissions of a S.I. Engine for Hybrid Powertrain Applications

Université de Bourgogne Franche-Comté-Jérémy Pelluet, Alan Keromnes, Luis Le Moyne
Université de Lyon - IFSTTAR AME ECO7-Alice Guille des buttes, Bruno Jeanneret
  • Technical Paper
  • 2020-37-0016
To be published on 2020-06-23 by SAE International in United States
Car manufacturers are introducing more and more hybrid powertrains in order to reach CO2 emissions targets and answer increasingly stringent pollutant emission regulations such as unburned hydrocarbons (HC), nitrogen oxides (NOx), carbon monoxide (CO) and particulate matter. The addition of an electric engine to a thermal engine introduces an additional degree of freedom in the energy management of the powertrain since two energy sources are available. Thus, the energy management system must also account for regulated pollutant emissions when devising an optimal energy management strategy to avoid a pollutant emission increase due to CO2 only driven optimisation. It is therefore necessary to model the influence of thermal engine operating conditions such as load and speed on these emissions to evaluate their concentration in the exhaust gases. This study presents an empiric modelling approach based on an extensive parametric study using a spark-ignition port-injection four-cylinder engine. Such a model intend to be used in the context of hybrid powertrain optimization. In order to reduce the computing costs required by ECU (Engine Control Unit), the number of…
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Pixelated-LEDs Car Headlight Design for Smart Driving and CO2 Reduced Emissions.

University of Versailles-Sidahmed Beddar, Jean-Baptiste Millet, Yasser Alayli
  • Technical Paper
  • 2020-37-0018
To be published on 2020-06-23 by SAE International in United States
The advent of Electroluminescent Diode (LED) technologies has been one of the major sources of energy reduction in the domestic lighting sector as well as in the automotive and aerospace fields. In vehicles, the use of LEDs allows a reduction of 110W to 40W useful for the function Dipped-beam is a gain of about 350W in energy consumption of the vehicle with a combustion engine (from 2 to 5g of CO2 per kilometer). In 2010, Adaptive Dipped Beam (ADB (also called glare-free high beam) appeared. The objective of the ADB is to adapt the beam to the presence of vehicles in both directions to improve the driver's long-range visibility without causing discomfort, distraction or glare to other road users. The ADB is a lighting function with high added value in terms of comfort and road safety. The new lighting technologies make this function more and more efficient and effective with a resolution and the number of pixels that increases Pixelated LEDs, by offering various advantages over other architectures, are gaining market shares. They are more…
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A Theoretical and Experimental Analysis of the Coulomb Counting Method and Estimation of the Electrified-Vehicles Electricity Balance Over the WLTP

European Commission Joint Research-Alessandro Tansini, Georgios Fontaras
Politecnico di Torino-Federico Millo
  • Technical Paper
  • 2020-37-0020
To be published on 2020-06-23 by SAE International in United States
The energy storage devices of electrified vehicles (Hybrid Electric Vehicles and Battery Electric Vehicles) are required to operate with highly dynamic current and power outputs, both for charging and discharging operation. When calculating the vehicle CO2 emissions and electrical energy consumption from a trip, the change in electrical energy content at vehicle-level has to be accounted for. This quantity, referred to as the electricity balance in the WLTP regulation, is normally obtained through a time-integration of the current or power supplied by the vehicle batteries during operation and the efficiency factor is often assumed to be unitary (as in the official type-approval procedure). The Joint Research Centre has collected experimental data from different electrified vehicles with regards to electrical energy use and battery State Of Charge (SOC) profile; the latter was used as a reference to quantify the actual vehicle electricity balance from a trip or driving cycle. In this work, the approach of using a simple Coulomb counting method with unitary efficiency for charging and discharging for the quantification of the vehicle electricity balance…