The module descriptors for this programme can be found below.

Modules shown are for the current academic year and are subject to change depending on your year of entry.

Please note that the curriculum of this programme is currently being reviewed as part of a College-wide process to introduce a standardised modular structure. As a result, the content and assessment structures of this course may change for your year of entry. We therefore recommend that you check this course page before finalising your application and after submitting it as we will aim to update this page as soon as any changes are ratified by the College.

Find out more about the limited circumstances in which we may need to make changes to or in relation to our courses, the type of changes we may make and how we will tell you about changes we have made.

Applications of Fluid Dynamics S5

Module aims

This module explores a number of applications of fluid dynamics to areas within and beyond aeronautics, in fields such as the fluid dynamics and heat transfer of physiological flows in the human body and the study of animal locomotion in fluids and its application to the bio-inspired design of unmanned air vehicles (UAVs). At the same time the course will deepen the understanding of the physics and governing equations of fluid dynamics. 

Learning outcomes

 On successfully completing this module, you should be able to:

1. Describe the essential characteristics and components of the cardiovascular and respiratory systems and apply dimensional analysis to derive key parameters describing physiological flows;  

2. Construct appropriate models to describe transport and exchange process, including defining equations, boundary conditions and deriving solutions in simple cases for flows, including Non-Newtonian and pulsatile flows.

3. Apply simple model equations to describe the transport of aerosols in inhaled and exhaled air and the use of CO2 concentration as a surrogate for room ventilation;

4. Understand the fluid mechanical basis of energy losses in the cardiovascular and respiratory systems and describe methods to quantify flow and transport in-vivo using magnetic resonance imaging (MRI).

5. Understand the morphology and kinematics of animal wings and how they affect aerodynamic performance in gliding and flapping flight; 

6. Examine the various modes of swimming employed by fish and how their fins, tails, and gaits, together with buoyancy contribute to the forces affecting motion;     

7. Describe the effect of fluid-fluid interfaces on locomotion: walking, swimming, and diving; 

8. Apply our understanding of animal locomotion in fluids to the bio-inspired design of UAVs.

Module syllabus

Bio-fluid mechanics. Nature and composition of blood and of respired air; length and time scales; characteristics of basic components and processes. Dimensional analysis (Womersley & other parameters); Brownian motion and diffusion; particle transport; diffusion equation. Modelling of non-Newtonian, pulsatile and wave-like flows; convective transport; exchange processes; equations and appropriate boundary conditions, flow losses.  Applications & illustrations: vFFR, CO2 monitoring, flow measurement techniques, application of computational methods. 

• Animal locomotion in fluids. Soaring and gliding: Wing morphology, geometry, and kinematics; Flight envelope; Steady aerodynamics; Manoeuvring; Formation flight. Flapping flight: Rigid wings; Dynamic stall; Forward flight; Hovering; Flexible wings; Flight control. Swimming: Fins, tails, and gaits; Buoyancy; Swimming modes. Locomotion on the water surface: Walkers; Swimmers; Divers. Bio-inspired design for UAVs: Bio-inspired swimming and flying.

Teaching methods

The module will be delivered primarily through large-class lectures introducing the key concepts and methods, supported by a variety of delivery methods combining the traditional and the technological.  The content is presented via a combination of slides, whiteboard and visualizer.

Learning will be reinforced through tutorial question sheets.

Assessments

This module presents opportunities for both formative and summative assessment.  

You will be formatively assessed through progress tests and tutorial sessions. 
You will have additional opportunities to self-assess your learning via tutorial problem sheets. 
You will be summatively assessed by a written closed-book examination (January) at the end of the module.
 
Assessment type Assessment description Weighting Pass mark Must pass?
Examination

2-hour closed-book written examination in January

100% 50% N
 
You will receive feedback on examinations in the form of an examination feedback report on the performance of the entire cohort.
You will receive feedback on your performance whilst undertaking tutorial exercises, during which you will also receive instruction on the correct solution to tutorial problems.
Further individual feedback will be available to you on request via this module’s online feedback forum, through staff office hours and discussions with tutors.