SHE Level 1
SCQF Credit Points 10.00
ECTS Credit Points 5.00
Module Code M1H321923
Module Leader Richard Danyi
School School of Computing, Engineering and Built Environment
Subject Mechanical Engineering
  • B (January start)

Pre-Requisite Knowledge

Higher grade physics or equivalent

Summary of Content

The aim of this module is to provide students with a foundation in the knowledge of mechanical engineering science and principles, and apply them to the design and analysis of hydrostatic, hydrodynamic and thermodynamic systems.


The teaching syllabus will cover the following areas: Introduction to Thermofluids: Definition of a fluid. Ideal and real fluids. Perfect gases. Compressible and incompressible fluids. Dimensions and units. Distinction between a fluid and a solid. Shear stress, velocity gradient and viscosity. Newtonian and non-Newtonian fluids. Description of phase. Fluid as a liquid, gas or vapour. Fluids: Fluid statics. Pressure in static fluids. Measurement of pressure, manometry. Descriptive treatment of flow. Comparison of laminar and turbulent flow. Reynold's Number. Continuity, momentum and energy equations. Use of energy equation to analyse single pipe systems. Thermodynamics: Basic definitions of systems. The perfect gas. The equation of state for a perfect gas. The 1st law of thermodynamics. The non-flow energy equation. Application to constant volume, constant pressure, isothermal, isentropic and polytropic processes.

Learning Outcomes

On completion of this module the student should be able to:1. demonstrate an understanding of fluids and their basic properties;2. measure and calculate fluid pressure;3. analyse flows, pressures and energies in pipe systems;4. apply the principles of work and energy in compressible fluid flow systems;5. evaluate heat, work and energy terms for closed systems using the 1st law of thermodynamics.

Teaching / Learning Strategy

To support the student learning experience this module's lectures and seminars are carefully structured to present a consistent and logical progression of topics and concepts. The lecture delivery will be enhanced by a variety of forms including, where appropriate, computer based animations and other multimedia forms. Feedback will be provided to students as follows: Students will be provided with feedback within two weeks of submission of all summative assessments providing information on strengths, weaknesses and suggestions for corrective action. Student feedback on teaching, learning and assessment will be sought at the end of the semester through a module evaluation questionnaire.

Indicative Reading

Michael J. Moran, Howard N. Shapiro, Fundamentals of Engineering Thermodynamics, John Wiley & Sons, Inc Seventh Ed 2011 Eastop,T.D and McConkey.A., Applied Thermodynamics. 6th Edition, Longman, 1997. Massey,B.S., Mechanics of Fluids. Van Nostrand Reinhold (UK), 2001 Johnson,A. and Sherwin,K., Foundations of Mechanical Engineering. Nelson Thornes, 2001. Hannah,J. and Hillier,M.J., Applied Mechanics. 3rd Edition, Longman, 1995. Yunis, A and Robert H Turner, Fundamentals of Thermal-Fluid Sciences, McGraw Hill International Edition 2001

Transferrable Skills

Problem Solving, Communication Skills: Written, Critical Evaluation

Module Structure

Activity Total Hours
Lectures (FT) 12.00
Assessment (FT) 9.00
Tutorials (FT) 20.00
Independent Learning (FT) 55.00
Practicals (FT) 4.00

Assessment Methods

Component Duration Weighting Threshold Description
Coursework 1 n/a 50.00 35% Report/Class test (750 or equivalent words)
Coursework 2 n/a 50.00 35% Report/Class test (750 or equivalent words)