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Unit information: Heat Transfer in 2015/16

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Unit name Heat Transfer
Unit code MENG31101
Credit points 10
Level of study H/6
Teaching block(s) Teaching Block 2 (weeks 13 - 24)
Unit director Dr. Saidani-Scott
Open unit status Not open

MENG20600 or equivalent



School/department Department of Mechanical Engineering
Faculty Faculty of Engineering

Description including Unit Aims

Heat Transfer is an advanced course which adopts a rigorous mathematical approach to the formulation and analysis of complex engineering problems in conduction, convection and radiation heat transfer. Students will be given an introduction to the Navier-Stokes, Continuity and Energy Equations, with emphasis placed on identifying the physical principles involved and the using relevant simplifications to find engineering solutions. Both analytic and computer-based solutions are explored. These studies are supplemented by a piece of coursework on the use of a computational software to solve a typical engineering problem, plus a wide range of worked examples, and problem sheets.

Intended Learning Outcomes

By the end of the course, students should be able to:

  • Correctly identify the physics behind a particular heat transfer problem, and explain relevant assumptions which can be applied to simply a given problem.
  • Solve the simplified equations for a range of one and two dimensional problems in conduction/convection heat transfer, including:

o Conduction in Cartesian, cylindrical or spherical coordinates with a range of boundary conditions

o Heat transfer from extended surfaces (fins)

o Convection in laminar flows over flat plates

o Convection in laminar flows through ducts or pipes

o Convection in high speed or turbulent flows

Simplify and solve equations for thermal radiation.

Teaching Information

There are 3 hours of lecture per week over 12 weeks, a 2 hour written examination at the end of the year, and a piece of coursework which students are advised to spend no more than 10 hours working on.

  • A substantial hand-out of printed notes is provided, covering all the topics in the course.
  • Solutions to worked examples are done in class and made available on Blackboard.
  • Worked solutions to past examination papers are provided for self-study.
  • MATLAB and Excel simulations of numerical heat transfer problems are provided.

A feedback session is held after submission of coursework to clarify common errors and highlight good practice

Assessment Information

2 hour written examination (90%) Coursework involving use of computational software (10%)

Reading and References

  • Fundamentals of Heat Transfer, 6th ed., Incropera et al. (John Wiley), 2007
  • Analysis of Heat & Mass Transfer, E.R.G. Eckert & R.M. Drake (Taylor & Francis), 1986
  • Heat Transfer, SI Units, 9th ed., J.P. Holman (McGraw Hill), 2001
  • Engineering Thermodynamics: Work and Heat Transfer, 4th ed., G.F.C. Rogers &Y.R. Mayhew, (Longman), 1992