44th International Vienna Motor Symposium

The PHOENICE Project: A Synergic Use of Innovative Technologies for the Next Generation of Green Hybrid Powertrains

Authors

Dr. T. Tahtouh, Institut Carnot IFPEN Transports Energie, IFP Energies Nouvelles, France; Dipl.-Ing. M. Brignone, Marelli Europe, Italy; Dipl.-Ing. J. Gareth, Johnson Matthey, UK; Dipl.-Ing. N. Demeilliers, In Extenso Innovation Croissance, France; Dipl.-Ing. G. Lucignano, Stellantis, Italy; Prof. F. Millo, Assoc. Prof. L. Rolando, Dipl.-Ing. G. Castellano, Politecnico di Torino, Italy; Dipl.-Ing. F. Bocchieri, FEV, Italy; Dipl.-Ing. J. Sierra Castellanos, Garrett Motion, France:

Year

2023

Print Info

Production/Publication ÖVK

Summary

The PHOENICE project aims at developing a C SUV-class plug-in hybrid (P0/P4) vehicle demonstrator whose fuel consumption and pollutant emissions are jointly minimized for real-world driving conditions. Technologies developed in PHOENICE are targeting a TRL 7 paying a specific attention to cost, industrialization, and to the use opportunity for various vehicle classes so as to maximize the economic and environmental impacts. This project is aiming to support the European automobile industry in the medium term and speed up the transition towards a more environmentally friendly mobility in terms of air quality and GHG emissions. The achievement of these ambitious goals will require the optimization of a highly efficient gasoline engine, relying on a dual dilution combustion approach with excess air and EGR, synergizing an innovative in-cylinder charge motion with high-pressure injection, novel ignition technologies, and an electrified turbocharger particularly relevant for hybrid architectures. The potential of alternative fuels produced by P2X processes will also be considered. To achieve the targeted near-zero-emissions in real driving conditions, the demonstrator vehicle will be equipped with a complete and dedicated aftertreatment system, including an electrically heated catalyst, a SCR and a GPF for abating NOx, particle number down to 10 nm, and non-regulated gaseous emissions. Finally, the vehicle overall efficiency will be increased with an exhaust waste heat recovery system for generating an additional electric power contribution for cabin heating or cooling, or for reducing the switch-on time of the internal combustion engine in cold conditions, thereby limiting the engine-out pollutant emissions such as particles.

ISBN

978-3-9504969-2-5

Lectures from the International Vienna Motor Symposium can be ordered from the Austrian Society of Automotive Engineers (ÖVK). Lectures can only be purchased in the form of the complete conference documents, individual lectures are not available.
When placing an order, please note the year/name of the event (e.g. "45th International Vienna Motor Symposium 2024") for the further ordering process.

Order
Back to search