Funding
Self-funded
Project code
ENGN4930219
Department
School of Electrical and Mechanical Engineering,Start dates
February and October
Application deadline
Applications accepted all year round
This PhD will be based in the School of Mechanical and Design Engineering and will be supervised by , and .
The work on this project will:
- enhance knowledge in performance and efficiency of highly flexible wing surfaces, which could be applied in aerospace and renewable energy industries
- enhance knowledge and design competitiveness in multiple applications as diverse as Micro Unmanned Aerial Vehicles to biomedical devices amongst many others
Flexible membrane surfaces such as parachutes, sails, insect wings and heart valves deform under fluid loading. This deformation is highly non-linear and has a strong dependence on initial conditions. The accuracy of such simulations has been difficult to achieve and is highly sensitive to the parameters being used. Any small errors are amplified in subsequent simulations.
Aeroelastic divergence and flutter are complex problems and continue to receive attention in the research community (Akhaven and Ribeiro, 2018). Here, the flexural rigidity is dominant for such surfaces and this has been modeled accurately (Cisonni et al, 2017) and is also available and used in commercial codes (Ozcatalbas et al, 2018). However, for membranes, the induced tension is dominant and more unstable.
This research will investigate, in detail, the parameters used in such simulations, to assess their sensitivities. The fluid-structure interaction will be obtained using CFD coupled with a structural code. Once successfully developed, the approach will be applied to a range of industrial applications.
We have an international reputation for applied research in behaviour and mechanics of advanced materials, including numerical studies of the deformation of flexible membrane surfaces to capture fluid-structure interactions (Knight et al, 2009, 2010). The techniques developed in these works will be extended to account for complex geometries and multi-directional material properties. The work can be exploited in many applications of industrial interest.
A parallel wind tunnel experimental program with use of digital image correlation and a separate tailored in-situ micro wind tunnel test within X-ray tomography equipment will be used to generate geometry for use in and to validate findings from the numerical studies.
The assessment of a large number of design alternatives and parameters will also be investigated for performance realisation and optimisation, as well as for the generation of scaling laws.
The work will enhance knowledge around the performance and efficiency of highly-flexible wing surfaces, which could be applied in aerospace and renewable energy industries. The work will also enhance knowledge and design competitiveness in multiple applications, from Micro Unmanned Aerial Vehicles to biomedical devices, among many others.
Fees and funding
Visit the research subject area page for fees and funding information for this project.
Funding Availability: Self-funded PhD students only
PhD full-time and part-time courses are eligible for the (UK and EU students only).
Entry Requirements
- You'll need a good first degree from an internationally recognised university (minimum second class or equivalent, depending on your chosen course) or a Master’s degree in Aeronautical, Mechanical or related engineering discipline
- In exceptional cases, we may consider equivalent professional experience and/or Qualifications
- English language proficiency at a minimum of IELTS band 6.5 with no component score below 6.0
How to apply
Please contact Dr Jason Knight (jason.knight@port.ac.uk) to discuss your interest before you apply, quoting the project code.
Apply
When you are ready to apply, please follow the 'Apply now' link on the Mechanical and Design Engineering PhD subject area page and select the link for the relevant intake.
Please note, to be considered for this self-funded PhD opportunity you must quote project code ENGN4930219 when applying.