TRITOS

TRansItions and Turbulence Of complex Suspensions

Coordinatore	KUNGLIGA TEKNISKA HOEGSKOLAN    more Spiacenti, non ci sono informazioni su questo coordinatore. Contattare Fabio per maggiori infomrazioni, grazie.
Nazionalità Coordinatore	Sweden [SE]
Totale costo	1˙998˙350 €
EC contributo	1˙998˙350 €
Programma	FP7-IDEAS-ERC Specific programme: "Ideas" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013)
Code Call	ERC-2013-CoG
Funding Scheme	ERC-CG
Anno di inizio	2014
Periodo (anno-mese-giorno)	2014-04-01   -   2019-03-31

 Partecipanti

#	participant	country	role	EC contrib. [€]
1	KUNGLIGA TEKNISKA HOEGSKOLAN  Organization address address: Valhallavaegen 79 city: STOCKHOLM postcode: 10044 contact info Titolo: Mrs. Nome: Heide Cognome: Hornk Email: send email Telefono: +46 87907128	SE (STOCKHOLM)	hostInstitution	1˙998˙350.00
2	KUNGLIGA TEKNISKA HOEGSKOLAN  Organization address address: Valhallavaegen 79 city: STOCKHOLM postcode: 10044 contact info Titolo: Prof. Nome: Luca Cognome: Brandt Email: send email Telefono: +46 87906870 Fax: +46 8205131	SE (STOCKHOLM)	hostInstitution	1˙998˙350.00

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 Obiettivo del progetto (Objective)

'The aim of this project is to forge a physical understanding of the transitions and of the turbulent flow of semi-dilute/dense non-colloidal suspensions, for different particle features and suspending fluids. It is estimated that 10% of the world energy consumption is due to the transport and handling of granular materials of which particle suspensions are an important part. A deep understanding of the mechanisms underlying the flow of particle suspensions, the transition to turbulence and the turbulence characteristics is crucial for many important practical applications involving engineered complex fluids, such as pastes and paper pulp. A better prediction and control of the flow of suspensions will therefore have a huge impact. Complex fluids are multiscale by nature where the physics at the microscale affects the macroscopic behaviour of the flow and vice versa giving rise to surprising and spectacular phenomena as well as making this one of the most important practical problem still to solve. Investigating the mechanisms by which the system microstructure determines the macroscopic flow properties and vice versa will not only give valuable insights into the nature of flowing suspensions but also will also lead to new ways to model and control it. Future generations of engineering CFD tools will have to contain models for complex suspensions. The fundamental approach proposed here, combined with challenging scientific and engineering examples backed up by experimental evidence, will make this possible and demonstrate it to a wider engineering community. The proposed project is based on highly accurate simulations of multiphase flow systems and state-of-the-art experiments. Such a holistic approach will enable us to understand the underlying mechanisms of instabilities and suspension turbulence and to develop accurate criteria for their prediction far in advance of what we could achieve with either approach separately.'