Use the Tab and Up, Down arrow keys to select menu items.
Engineering design reports, design for fatigue, fasteners, welded joints, cranes: use of engineering codes, pressure vessel design, hydraulic machinery.
Mechanical A StreamIn terms of the design material students are taught more in-depth engineering design methods than ENME 301 and cover procedures that are not included in the engineering science subjects. In particular, it furthers their skills in engineering report writing, calculation sets and drawing presentation. It introduces the use of standards. Overall students are brought to a level where they can undertake a substantial engineering design problem, in a methodical manner, and can produce a professional quality design report.In terms of the production engineering module, the course continues by introducing the concepts of production lines and various methods of production management, manufacturing maintenance and design for the supply chain in the production environment.Biomedical B StreamStudents will achieve the same learning outcomes as for the Mechanical stream, but with a biomedical focus and examples. Entrance into Stream B is by request with information on how to do so provided in prerequisite course ENME301.
On successful completion of this course students will be able to:Produce a conceptual and detailed design solution for an open-ended system that is only partially defined at the conceptual levelProduce a professional design report including calculation set, and drawings.Design pressure vessels by creating a conceptual solution to a problem and applying standards to complete the detailed design Design components and steel structures using sections, bolted joints and welds, subjected to fatigue loadingProduce design solutions that accommodate functional constraints as well as manufacturability, production economics, aesthetics, and safety.Understand design responsibilities regarding risk, reserve/safety factors, and ethical considerationsUnderstand modern production management methods
This course will provide students with an opportunity to develop the Graduate Attributes specified below:
Critically competent in a core academic discipline of their award
Students know and can critically evaluate and, where applicable, apply this knowledge to topics/issues within their majoring subject.
ENME301
Keith Alexander
Malcolm Taylor and Debbie Munro
Assessment details above apply to Mechanical A StreamPlease see below for Biomedical B Stream Assessment Details24/07/2019 Assignment 1 (5%)31/07/2019 Assignment 2 (5%)21/08/2019 Assignment 3 (20%)2/10/2019 Assignment 4 (30%)11/10/2019 Final Report (20%)18/10/2019 Bio Med Device Cup (20%)
Bártolo PJ. Ceretti, Da, SJ, Gay JDC, Rodriguez CA; Biomedical devices: Design, prototyping, and manufacturing ; Wiley, 2016.
Shigley; Mechanical Engineering Design ; 1st Metric Edition; McGraw Hill, 1986.
Weinger MB, Wiklund ME, Gardner-Bonneau DJ; Handbook of Human Factors in Medical Device Design ; Taylor & Francis Group, 2010.
DeMarco, Carl T; Medical device design and regulation ; ASQ Quality Press, 2011.
Deutschman, Aaron D. , Michels, Walter J., Wilson, Charles E; Machine design : theory and practice ; Macmillan, 1975.
Hamrock, Bernard J. , Jacobson, Bo O., Schmid, Steven R; Fundamentals of machine elements ; WCB/McGraw-Hill, 1999.
Hosking, A K. , Harris, M R; Applied Mechanical Design ; 3rd Edition; H & H Publishing, 1997.
Ogrodnik, Peter J; Medical device design : innovation from concept to market ; 1st ed; Elsevier/Academic Press, 2013.
Shigley. , Mischke; Mechanicl Engineering Design ; 7th Metric Edition; 2003.
Domestic fee $956.00
International fee $5,250.00
* 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 Mechanical Engineering .