Loading…

Loading grant details…

Active HORIZON European Commission

Microscale enabled advanced flow and heat transfer technologies featuring high performance and low power consumption


Funder European Commission
Recipient Organization Sabanci Universitesi
Country Turkey
Start Date Mar 01, 2023
End Date Feb 28, 2027
Duration 1,460 days
Number of Grantees 19
Roles Associated Partner; Participant; Coordinator
Data Source European Commission
Grant ID 101082394
Grant Description

With the emergence of Industry 4.0, electronic and digital devices are incorporated into almost all high tech applications.

There has also been a notable shift towards compact electronic devices, which requires more intense operating powers — leading to enormous heat dissipation.

Thus, whilst devices are increasingly becoming portable and powerful, thermal management techniques are arguably not catching up at the same rate. Hence, continuous improvement and innovative approaches are needed.

In this regard, microchannel-based techniques present innovative possibilities to tackle thermal management and cooling issues in modern appliances across various industries, aligning with the trend to adopt more sustainable approaches and the EU 2016 legislation for heating and cooling.

Consequently, our 'Micro-FloTec' project adapts an international, multidisciplinary, and collaborative approach to exchange expertise from 17 research institutions and two industrial partners to trigger significant advancements and agile development for heat transfer and thermal management solutions.

The consortium shares robust experience and skills related to heat transfer enhancement, large-scale electrical energy storage via thermal processes, new generation materials science, multi-phase flow, flow and heat transfer of high-temperature rotating parts, design and modelling for energy-efficient control systems, marketing and entrepreneurship skills, amongst others.

Based on the appraisal of the current state-of-the-art literature and technologies, we aim to tackle problems within morphological optimization of multiphase heat transfer performance and flow resistance reduction, surface modification techniques, and application of multi-phase physics for performance prompting.

Our project will hopefully achieve cost-effective and sustainable solutions, initiate future advancements and investigations, and contribute towards the EU's 2050 long-term strategy for climate and energy saving goals.

All Grantees

University of British Columbia; University of Shanghai for Science and Technology; Kasetsart University; The University of Hertfordshire Higher Education Corporation; Imperial College of Science Technology and Medicine; Universite de Rennes; South China University of Technology; Seoul National University; Universite de Strasbourg; Zhejiang University; Universita Degli Studi Di Padova; Sabanci Universitesi; Sun Yat-Sen University; Universidade de Aveiro; Nanyang Technological University; 河南科隆集团有限公司; Beihang University; Picadvanced, Sa; Stellenbosch University

Advertisement
Apply for grants with GrantFunds
Advertisement
Browse Grants on GrantFunds
Interested in applying for this grant?

Complete our application form to express your interest and we'll guide you through the process.

Apply for This Grant