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| Staff directory | A-Z index | Site map |
| Undergraduate |
(ENG)
|
Leader: T F Berreen
Offered:
Clayton First semester 2005 (Day)
Malaysia First semester 2005 (Day)
OS-IRAN First semester 2005 (Day)
Caulfield Second semester 2005 (Day)
Clayton Second semester 2005 (Day)
Malaysia Second semester 2005 (Day)
Synopsis: Dimension, units and error estimates. Kinematics of particles and rigid bodies. Free body diagrams The concept of work, energy and power Forces and torques applied to rigid bodies undergoing translation or rotation The relevance of these to some common engineering mechanisms. Free and damped vibration and engineering applications. Kinematics of gears and geared systems including compound epicyclic gears. Friction, and the kinetics of belts and belt drives.
Objectives: The student is expected to: Knowledge and Understanding 1. Understand the importance of presentation of engineering results in relevant units and significant figures 2. Understand the fundamentals of kinematics and kinetics of particles and rigid bodies 3. Apply these principles to solving engineering problems involving: ? Simple vibrating systems of masses, springs and dampers ? Analysis of simple engineering mechanisms ? Kinematics and power transmission capability of gears and belts Skills 4. Express engineering solutions in a realistic and logical format using the appropriate units, dimensions and accuracy 5. Appropriate use of free body diagrams as part of the overall solution 6. Appreciation of the differences between kinematics and kinetics 7. Applying these skills to solve engineering mechanics problems. Attitudes 8. Check the consistency of the units and dimensions used in the solution 9. Create large and well defined free body diagrams with the appropriate coordinate system 10. Ability to relate kinematics and kinetics in solving engineering mechanics problem.
Assessment: 10% mid-semester test, 10% laboratory/problem solving,10% design, build and test project, 70% final exam (2 hours)
Contact Hours: 3 hours lectures, 2 hours of problem solving/laboratory and build and test design projects and 7 hours private study per week
Prerequisites: VCE Physics 3/4 or ENG1080 recommended
Prohibitions: ENG1401