Unsteady aerodynamics of micro drones for Offshore Wind Farm Monitoring

4-year PhD with Integrated Studies.  
 
Aim of the project. The aim of the project is to investigate, through bio-inspired fundamental research, a mechanism to exploit wind gusts to keep small flyers afloat. Recent work led by Viola and published in Nature (https://doi.org/10.1038/s41586-018-0604-2), reveals that the dandelion exploits a highly porous wing to form a fluid vortex, which has never been observed before, and that slows down its descent velocity. It also revealed that the dandelion exploits wind gusts to gain altitude and slow down its descent.  Computational fluid dynamics simulations will be undertaken to study the underlying principles of this uplifting mechanism and to underpin the design of a dandelion-inspired drone: the dandidrone.  
 
Industrial context. Offshore wind energy is set to rise nearly tenfold in the next 10 years, and up to 1 TW in 2050. This is equivalent to a wind farm of the size of the North Sea. To monitor such a wide offshore area remotely, it will be necessary to develop aerial sensors with a step increase in resiliency and endurance. Nature offers ingenious solutions to this challenge. In fact, plant seeds maximise their endurance and dispersal to ensure the proliferation of the plant. This project will address this industry-driven challenge of maximising endurance of small flyers by undertaking fundamental research inspired by the most successful of the plant dispersal mechanisms: that one of the dandelion seed.
 
Fluid Mechanics Context. Similar mechanisms, where a passive body scavenges energy from flow fluctuations for locomotion, have already been observed. For example, some bodies with ad-hoc shapes such as pyramids can passively hover by exploiting oscillating flow. With an akin mechanism, swimmers scavenge flow fluctuations generated by other swimmers or obstacles to swim against the current. Beal et al. (https://doi.org/10.1017/S0022112005007925), for example, showed a dead fish swimming upstream in the wake of a semi cylinder. Understanding these mechanisms that exploit the environmental flow fluctuations to gain altitude or to swim upstream are paramount to enable new engineering solutions for zero- and low-energy transport
 
The student will join the Centre for Doctoral Training (CDT) in Wind and Marine Energy Systems and Structures (WAMESS). Please see https://edin.ac/2zvpMb2 for more information on the programme of study including the list of taught courses.  

Further Information: 

Closing Date: 

Wednesday, June 10, 2020

Principal Supervisor: 

Assistant Supervisor: 

Eligibility: 

Minimum entry qualification - an Honours degree at 2:1 or above (or International equivalent) in a relevant science or engineering discipline, possibly supported by an MSc Degree. Further information on English language requirements for EU/Overseas applicants.

The applicant should have an undergraduate degree in Mathematics, Physics, Engineering or equivalent, and a solid fluid mechanics background at undergraduate level.  
 
Experience in computational fluid dynamics is desirable but not necessary.  
 
Applicants from underrepresented groups and that would contribute to improve diversity within VOILAb are particularly encouraged to apply.  

Funding: 

Stipend and Tuition Fees (at the UK/EU fee rate only) are available.

Overseas students may apply, but only if external funding has already been secured to cover the difference between the UK/EU fee rate and the Overseas fee rate.
Further information and other funding options.

Informal Enquiries: