PhD Studentship: Improved physical modelling techniques for new high capacity floating offshore wind turbines

Improved physical modelling techniques for new high capacity floating offshore wind turbines

DoS: Dr Martyn Hann ([email protected] , tel.: +44 1752 586130)

2nd Supervisor: Dr Sanjay Sharma ([email protected] )

3rd Supervisor: Dr Edward Ransley ([email protected] )

4rd Supervisor: Dr Craig McNeile ([email protected] )

5th Supervisor: Dr Chong Ng ([email protected] )

Applications are invited for a three-year PhD studentship. The studentship will start on         01 October 2024.

Project Description

Floating offshore wind turbines (FOWT) are widely seen as an essential part of many countries’ drive to achieve ‘net-zero’. However, the Levelised Cost of Energy of FOWT is still high compared with fixed foundation offshore wind, and therefore additional innovation is needed.

Scaled physical modelling of FOWT is a critical stage in the development of new design innovations, but represents a significant challenge. Hydrodynamic loads applied to platform and moorings from waves and currents are modelled in wave tanks, such as the COAST laboratory’s Ocean Basin. However, aerodynamic loads also have a significant influence on the FOWT system’s response and cannot be ignored. The application of these aerodynamic loads without introducing unwanted scale effects to the experiment represents a significant challenge.

This PhD will explore the use of two techniques for overcoming this challenge, to enable the testing of high capacity FOWT. The first technique involves the wind turbine being replaced with thrusters which apply correctly scaled aerodynamic loads to the floating platform. The generated loads are controlled in real time using a surrogate model ‘trained’ using results from more complex numerical models. In the second approach COAST’s new 3 m x 2.8 m wind generator will be used to generate a wind field over the Ocean Basin. A model turbine will be installed on the scaled floating platform to generate the aerodynamic loads.      

Supported by the ORE Catapult, the successful candidate will gain skills in both state of the art physical and numerical modelling of FOWT. It is envisioned that the student will work with industry partners to support their physical modelling within the COAST laboratory.

Eligibility

Applicants should have a first or upper second class honours degree in an appropriate subject and preferably a relevant Masters qualification.

If your first language is not English, you will need to meet the minimum English requirements for the programme, IELTS Academic score of 6.5 (with no less than 5.5 in each component test area) or equivalent.

The studentship is supported for 3 years and includes full Home tuition fees plus a stipend of £18,655 per annum (2024/25 rate).  The studentship will only fully fund those applicants who are eligible for Home fees with relevant qualifications.  Applicants normally required to cover International fees will have to cover the difference between the Home and the International tuition fee rates.

If you wish to discuss this project further informally, please contact Dr Martyn Hann [email protected]

To apply for this position please click the Apply button above.

Please clearly state the name of the studentship project that you are applying for on the top of your personal statement.

Please see here for a list of supporting documents to upload with your application.

For more information on the admissions process generally, please contact [email protected] .

The closing date for applications is 12 noon on 5 July 2024. Shortlisted candidates will be invited for interview shortly after the deadline.