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Module details for 2024/25.

15 credits

FHEQ Level 5

Pre-Requisite

Engineering Maths 1A
Engineering Maths 1B
Engineering Thermodynamics

Module Outline

This module introduces the basic concepts of Fluid Mechanics with applications in the field of Engineering in mind. It teaches the fundamental techniques used to understand the behaviour of fluids at rest and in motion.
Many engineering applications/devices need to interact with a fluid medium (air, water, other...) to achieve a desired objective; an aircraft moving in air, a ship sailing on water, or a wind turbine extracting power from wind are some examples. In each of the above and many other scenarios an engineer needs to understand the behaviour of the fluid when it interacts with the device to fully characterise the performance of the device. Fluid Mechanics fundamentals are essential to achieve this.
As an engineer one needs to tackle fluid related phenomena to design useful applications, be it in the field of transport, energy, medicine, sports, or everyday household appliances. Without a good understanding of the fundamentals of Fluid Mechanics it would be practically impossible to produce successful designs.
This module takes the student, in a step-by-step manner, from basic A-level physics and related mathematics to the theory and equations that describe stationary and moving fluid. The student will be introduced to practical application of such theories to simple everyday examples involving fluid flow. The knowledge learned here is essential for understanding further applied topics in the Mechanical/Automotive BEng/MEng courses such as Numerical modelling or Advanced thermofluids and for carrying out Fluid Mechanics based final year projects.

List of topics
• Fundamentals: historical perspectives, fluid properties, concept of pressure.
• Fluid statics: force on submerged surfaces, buoyancy.
• Concepts in fluid flow behaviour: motion of a fluid particle, mass continuity, laminar and turbulent flow, momentum equation, Navier Stokes equations for simple 2D fluid flow.
• Boundary-layer theory and applications: velocity profile, skin friction and form drag, dimensionless groups, pipe flow networks, frictional resistance of moving bodies, lift and drag on aerofoil sections.
• Potential flow: streamlines and the stream function for various simple flows (and combinations), the Kutta-Joukowski law.
• Compressible flow: isentropic flow behaviour, total and static quantities, the speed of sound, flow in a convergent-divergent nozzle.
• Flow-measuring devices: Venturi meter, orifice plate, Pitot static tube.

The syllabus covers the following AHEP4 learning outcomes: C1, C2, C3, M1, M2, M3

Library

Fluid Mechanics by J. F. Douglass, J. M. Gassiorek, J. A. Swaffield and L. B. Jack
Fluid Mechanics by White
Mechanics of Fluids by B. Massey
Physical Fluid Dynamics by D. J. Tritton
Boundary Layer Theory by H. Schlichting
Tables for the Compressible Flow of Dry Air by E. L. Houghton and A. E. Brock

Module learning outcomes

Have a critical understanding of well established principles in fluid mechanics

Deploy well established techniques of analysis to engineering problems in fluid mechanics

Apply underlying concepts outside the context they were first studied

Understand the limits of knowledge in fluid mechanics and how this influences analysis

View timetable

Timing

Submission deadlines may vary for different types of assignment/groups of students.

Weighting

Coursework components (if listed) total 100% of the overall coursework weighting value.

How to read the week pattern

The numbers indicate the weeks of the term and how many events take place each week.

Dr Vasudevan Kanjirakkad

Assess convenor
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