Sort by
Refine Your Search
-
Listed
-
Category
-
Employer
- ;
- ; The University of Manchester
- Cranfield University
- University of Sheffield
- ; Brunel University London
- ; Swansea University
- ; University of Birmingham
- ; University of Surrey
- University of Cambridge
- ; University of Leeds
- ; University of Sheffield
- ; University of Southampton
- ; University of Warwick
- Brunel University
- Imperial College London
- University of Nottingham
- 6 more »
- « less
-
Field
-
Discipline: Engineering & Technology, Fluid Dynamics, Mechanical Engineering, Other Engineering Research area and project description: Droplets are ubiquitous in nature, industry, and our everyday
-
model of high-pressure mechanical seals. Apply Computational Fluid Dynamics (CFD): Simulate gas film flow within the microscopic seal gap. Couple CFD with Structural Models: Study the fluid-structure
-
School/Faculty: Mechanical Engineering Eligibility: UK Only Funding: School of Mechanical Engineering Studentship, in collaboration with SLB, providing the award of full academic fees, together
-
Application deadline: 01/08/2025 Research theme: Turbulence, Fluid Mechanics, Offshore Conditions, Renewable Energy, Hydrodynamics, Experiments This 3.5 year PhD is fully funded for applicants from
-
Application deadline: All year round Research theme: Applied Mathematics, Mechanical and Aerospace Engineering, Fluid Dynamics How to apply:uom.link/pgr-apply-2425 How many positions: 1 This 3.5
-
capture technologies. In this project, you will: Develop a 3D Digital Model: Create an advanced computational model of high-pressure mechanical seals. Apply Computational Fluid Dynamics (CFD): Simulate gas
-
a fast-track career in Wind Turbine Industry that is allied to an environmentally sustainable energy future, or academic career in the aerodynamics, fluid mechanics and aeroacoustics fields. Joining
-
“lattice” version of space and time, similar to the finite difference approach in computational fluid dynamics. Using this Lattice QCD method, Centre Vortex fields will be analysed to understand particles
-
Computational Fluid Dynamics (CFD) and Conjugate Heat Transfer (CHT) modelling, which captures both the fluid & solid domains, as required to develop this understanding for engine-representative geometries and
-
project offers a unique opportunity to develop autonomous microswimmers, which are bioinspired structures at the micrometre scale that can propel themselves through fluids, mimicking natural swimming