SubsidieMeestersNon-Stationary Non-Homogeneous Turbulence
This project aims to revolutionize turbulent flow prediction through innovative laboratory, computational, and theoretical methods, leading to a new understanding of non-stationary and non-homogeneous turbulence.
Projectdetails
Introduction
A wide range of radical technological breakthroughs are needed across all industries and engineering because of the dramatic current climatic, environmental, and population growth constraints on energy, energy efficiency, pollution, and emissions.
Importance of Turbulent Flows
Turbulent flows are a key limiting factor in a vast range of these industries, including:
- Aeronautical
- Automotive
- Chemical
- Pharmaceutical
- Environmental engineering
Step-change technological innovations in these industries therefore require rapid and reliable turbulent flow prediction methods, which are currently unavailable. The stalemate in turbulence prediction methods reflects an 80-year stalemate in our fundamental understanding of turbulent flows.
Recent Advances
The past 5 years, however, have seen a number of advances that overturn cornerstone turbulence textbook material and create an unprecedented opportunity for a potentially decisive breakthrough in our fundamental and general understanding of turbulent flows, which are typically non-stationary and/or non-homogeneous.
These recent advances concern non-stationarity and non-homogeneity in fundamental ways and open new research opportunities with many new questions and hypotheses.
Project Objectives
This project will seize these new research opportunities with a combination of laboratory, computational, and theoretical methods and approaches applied to a variety of turbulent flows.
Expected Outcomes
The expected outcome is a transformative, entirely new and extensive, fundamental understanding and theory of non-stationary and/or non-homogeneous turbulence, and a consequent road map for future disruptive turbulent flow prediction methods.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.499.514 |
| Totale projectbegroting | € 2.499.514 |
Tijdlijn
| Startdatum | 1-10-2022 |
| Einddatum | 30-9-2027 |
| Subsidiejaar | 2022 |
Partners & Locaties
Projectpartners
- CENTRE NATIONAL DE LA RECHERCHE SCIENTIFIQUE CNRSpenvoerder
- CENTRALE LILLE INSTITUT
Land(en)
Vergelijkbare projecten binnen European Research Council
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|---|---|---|---|---|
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Beyond self-similarity in turbulence
This project aims to develop and validate a theory for intermediate-strain turbulence using machine learning and advanced simulations to enhance engineering applications like wind energy and UAV efficiency.
Breaking through: The Impact of Turbulence on the Gas-Liquid Interface
GLITR aims to revolutionize the understanding of mass transport across gas-liquid interfaces by using tailored turbulence to explore its impact on fluid mechanics and interfacial phenomena.
Turbulence-On-a-Chip: Supercritically Overcoming the Energy Frontier in Microfluidics
The SCRAMBLE project aims to induce turbulent flow in microchips using supercritical fluids to enhance energy transfer processes, potentially revolutionizing microfluidic applications and energy technologies.
Generative Understanding of Ultrafast Fluid Dynamics
The project aims to harness ultra-fast fluid dynamics through advanced computational methods to optimize micro-manufacturing and energy conversion, delivering innovative solutions and insights.
Interaction of Elasto-inertial Turbulence and material microstructure – INTER-ET
The INTER-ET project aims to advance the understanding of elastic turbulence in complex fluids through innovative simulations and experiments, enhancing mixing and heat transfer for various applications.