Sort by
Refine Your Search
-
Listed
-
Category
-
Country
-
Employer
- ;
- ; The University of Manchester
- University of Manchester
- Cranfield University
- University of Nottingham
- University of Cambridge
- ; University of Birmingham
- ; University of Nottingham
- ; Swansea University
- ; University of Surrey
- Harper Adams University
- University of Sheffield
- ; Cranfield University
- ; The University of Edinburgh
- ; University of Warwick
- ; Brunel University London
- ; Loughborough University
- ; Newcastle University
- ; University of Exeter
- ; University of Sheffield
- ; University of Bristol
- ; University of Oxford
- ; University of Plymouth
- ; University of Southampton
- AALTO UNIVERSITY
- Abertay University
- ; EPSRC Centre for Doctoral Training in Green Industrial Futures
- ; UWE, Bristol
- ; University of Cambridge
- ; University of Reading
- Heriot Watt University
- Imperial College London
- THE HONG KONG POLYTECHNIC UNIVERSITY
- University of Liverpool
- University of Oxford
- University of Warwick
- ; Aston University
- ; Coventry University Group
- ; Durham University
- ; Lancaster University
- ; Queen's University Belfast
- ; University of Bradford
- ; University of Essex
- ; University of Greenwich
- ; University of Huddersfield
- ; University of Hull
- ; University of Leeds
- ; University of Portsmouth
- Brunel University
- Durham University
- KINGS COLLEGE LONDON
- UNIVERSITY OF VIENNA
- University of Leicester
- University of Newcastle
- Utrecht University
- 45 more »
- « less
-
Field
-
early 2030s. One prominent HTGR configuration is the pebble-bed reactor, in which spherical fuel elements (pebbles) are densely packed within the core, creating a complex and heterogeneous thermal-fluid
-
film flow within the microscopic seal gap. Couple CFD with Structural Models: Study the fluid-structure interaction (FSI) and dynamic response of seal rings under real-world conditions. Collaborate with
-
-state physics, fluid dynamics, solid-dynamics, and fracture/degradation; all in a highly transient and non-linear system. In this project we will extend multi-component, multi-phase field frameworks
-
demonstrate the utility of an adaptive mesh refinement approach in interface resolving Computational Fluid Dynamics (CFD) simulations of flow boiling at conditions relevant to nuclear thermal hydraulics
-
include: Developing innovative serration and permeable surface designs to further reduce trailing edge noise. Conducting detailed fluid dynamics, aerodynamics, and aeroacoustics investigations to understand
-
; EPSRC Centre for Doctoral Training in Green Industrial Futures | Edinburgh, Scotland | United Kingdom | 2 months ago
of an accurate and generalisable density Equation of State model (EoS). This is especially challenging near the critical point and the Widom line, where there are large gradients in fluid properties. This project
-
. The successful candidate will be part of a team working towards advancing the modelling capabilities of geothermal systems and contribute to the following objectives: • Investigating fluid flow
-
the Clean Energy Processes (CEP) Laboratory . The CEP team conducts research on fundamental aspects of thermodynamics, fluid flow, heat and mass transfer processes with applications to the development
-
mechanisms, with the current generation having significant drawbacks, including low energy efficiency, high operating voltage or temperature. This project will develop the materials, methods, and designs
-
nanosheets, nanotubes, etc) or hybrid (e.g. boron carbon nitride). Similarly, while water is the most studied coolant liquid, realistic applications involve dielectric fluids (e.g. benzene, pentane). Molecular