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Portable Nano-Particle Emission Measurement System

par Webmestre - publié le , mis à jour le

The PEMs4Nano project (P4N) addresses the development (based on current direct injection gasoline engines) of measurement procedures down to 10nm, providing a contribution to future regulation on particle emissions, in particular in real driving conditions. The activities planned in the project will also support the understanding, measurement and regulation of particle emissions below 23 nm (with the threshold of at least 10 nm).

Societal concerns for the environment include both fuel consumption and noxious emissions, as well as the awareness that meeting CO2-goals with newest technologies may also lead to the emission of smaller nanoparticles that are undetected by current certification procedures. Hence P4N has the goal to develop measurement procedures that are robust and reliable for both the development of the new engine technologies, as well as serving as a solid basis for new regulations.

This has the advantage of establishing a solid content link between development activities and regulation. Two complementary measurement systems will be optimized for use in the development laboratory and for mobile testing based on current technologies. Given the numerous parameters associated with the engine (combustion and exhaust systems) technologies and measurement procedures ; physico-chemical and data-driven simulations combined with optimization is proposed to establish valuable correlations between measurements made in the development laboratory and thus finally those measured on the road.

PEMs4nano thus proposes a two path approach that connects tailpipe measurements with the origin and the evolution of the particles, resulting in a seamless approach from the laboratory to the field test capabilities. Investigations of particle characteristics (incl.composition, size and morphology) and their influence on successful measurements will also be carried out using various load profiles that make up real-driving to validate the application of the measurement procedure.

Two teams from the University of Lille 1 Sciences et Technologies are involved in the project : UMR CNRS "Trace Analysis" 8523 (Laser Physics Laboratory, Atoms and Molecules - PhLAM) and "Combustion" of the UMR CNRS 8522 (Physical Chemistry Laboratory of Combustion Processes and Atmospheric - PC2A). Both teams have a long standing collaboration on the implementation of combustion in laser techniques, as part of the Centre for Studies and Research Lasers and Applications (CERLA) LABEX Cappa (Chemical and Physical Properties of the Atmosphere) or other national projects (ANR SOOT) or regional (CPER CLIMIBIO).

Scientific contact for the University of Lille 1 :
Cristian FOCSA, Laboratoire PhLAM

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