Use the Tab and Up, Down arrow keys to select menu items.
Fluid properties such as density and viscosity. Fluid statics, Bernoulli's equation, pipe flow profiles, pressure drop and frictional losses under flow. Laminar and turbulent flow. Pumps, compressors and fans. Thermodynamic properties such as heat capacity, latent heat of fusion and evaporation. Introduction to conductive and convective heat transfer, film and overall heat transfer coefficients. Radiation. Graphical analysis of common thermodynamic cycles, including the Carnot cycle and heat pumps.
By the end of the course, you will be able to:Demonstrate understanding of the fundamental concepts of fluid mechanics and thermodynamics relevant to industrial design.Apply the fundamental theories and equations of fluid flow to problem scenarios relating to common applications.Apply the fundamental theories and equations of heat transfer to problem scenarios relating to common applications.Work as a team for the design and production of laboratory-based tasks and reporting thereon.Produce clear, concise summaries on material generated throughout laboratory activities and communicate concepts to peers.
1) either PROD110 or ENGR101; and 2) either 15 points of MATH/EMTH at 100-level or 15 points of PHYS at 100-level
Euan Coutts
Alison Lowery
Nick Emerson
Online LEARN quiz assignments Week 5, 7, 11 10%In-class quizzes 9 quizzes during Friday lecture 10%Waterclock assignment Week 9 demo/poster 40%Final Exam (exam period 14-25.06.21) 40%Total 100%
Cengel, Yunus A. , Cimbala, John M; Fundamentals of thermal-fluid sciences ; 4th ed; McGraw-Hill Higher Education, 2012.
White, M. Frank; Fluid mechanics ; McGraw-Hill Higher Education, 2017.
Domestic fee $986.00
International fee $5,500.00
* All fees are inclusive of NZ GST or any equivalent overseas tax, and do not include any programme level discount or additional course-related expenses.
For further information see School of Product Design .