Module Overview

Ordinary differential equations: classification (linear/non-linear, stiff/non-stiff); reduction to first order autonomous form; stiffness and stability; explicit and implicit numerical methods; stability criteria; computational efficiency.

Algebraic equations: direct and iterative solution methods for linear systems; fixed-point iteration and Newton iteration for non-linear systems; convergence criteria; stopping criteria.

Heat transfer: modelling of steady state conduction; simulation of transient conduction; various boundary conditions; internal heat generation.

Definition of Computational Fluid Dynamics, how it was developed and where it is used i.e. Heating ventilation and air conditioning applications and Fire engineering.

Continuity, momentum and energy equations conservation and non-conservation formulations 

Discretisation of flow equations. Explicit and implicit solution schemes.

Turbulence modelling.

Finite difference and finite volume methods

Derivation of a simple flow solution techniques e.g. Couette flow, Diffusion problems, simple convection problems.

Geometry modelling, transformation and grid generation.

Use of Computational Fluid Dynamics in the design process.

Analysis of error minimisation and convergence.

Laboratories will include ventilation and air conditioning modelling, combined convection and radiation heat transfer, cooling/heating system modelling, fluid mixing modelling and optimisiation of building design. These will be implemented using the ANSYS/CFX computational fluid dynamics software package and IES software package.

Class lectures, self-directed learning, computer laboratory tutorials.

Module Content & Assessment
Assessment Breakdown	%
Formal Examination	50
Other Assessment(s)	50