Courses & Units
Dynamics and Vibrations ENG719
Introduction
Students learn, through theory and laboratory experiments, to solve problems in dynamics and vibrations, using Newtonian kinematics and kinetics of rigid bodies. The course commences with planar motion with analysis of velocities then moving onto Coriolis acceleration of rigid bodies. Building upon the concepts of kinetics of particles, an introduction is made to rigid body kinetics using Newtonian mechanics based on force, mass and acceleration, work/energy and impulse/momentum methods. The final part of the course introduces mechanical vibrations. Commencing with single degree of freedom undamped vibrations then damped vibrations. Single degree of freedom forced vibrations without damping is discussed in addition to the magnification factor and its importance. The course concludes with damped forced vibrations, thus forming a comprehensive fundamental understanding of mechanical vibrations.
Summary
Unit name | Dynamics and Vibrations |
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Unit code | ENG719 |
Credit points | 12.5 |
College/School | College of Sciences and Engineering School of Engineering |
Discipline | Engineering |
Coordinator | Doctor Jason Ali-Lavroff |
Delivered By | University of Tasmania |
Availability
Location | Study period | Attendance options | Available to | ||
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Hobart | Semester 2 | On-Campus | International | Domestic |
Key
- On-campus
- Off-Campus
- International students
- Domestic students
Note
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Key Dates
Study Period | Start date | Census date | WW date | End date |
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Semester 2 | 10/7/2023 | 8/8/2023 | 28/8/2023 | 15/10/2023 |
* The Final WW Date is the final date from which you can withdraw from the unit without academic penalty, however you will still incur a financial liability (refer to How do I withdraw from a unit? for more information).
Unit census dates currently displaying for 2023 are indicative and subject to change. Finalised census dates for 2023 will be available from the 1st October 2022. Note census date cutoff is 11.59pm AEST (AEDT during October to March).
Learning Outcomes
- Solve mechanical engineering problems involving rigid body motion and vibration using advanced theory based on Newtonian Mechanics.
- Justify recommendations to experiment based problem involving dynamics and vibration using advanced theory and experiential knowledge.
- Design practical solutions to mechanical engineering problems involving dynamics and vibration.
Fee Information
Field of Education | Commencing Student Contribution 1,3 | Grandfathered Student Contribution 1,3 | Approved Pathway Course Student Contribution 2,3 | Domestic Full Fee 4 |
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030701 | $1,037.00 | $1,037.00 | not applicable | $2,938.00 |
1 Please refer to more information on student contribution amounts.
2 Please refer to more information on eligibility and Approved Pathway courses.
3 Please refer to more information on eligibility for HECS-HELP.
4 Please refer to more information on eligibility for FEE-HELP.
If you have any questions in relation to the fees, please contact UConnect or more information is available on StudyAssist.
Please note: international students should refer to What is an indicative Fee? to get an indicative course cost.
Requisites
Prerequisites
(ENG105 or KAA111) and KMA154Mutual Exclusions
You cannot enrol in this unit as well as the following:
ENG211Teaching
Teaching Pattern | 3 x 1hr lectures weekly, 1 x 1hr tutorial weekly and 3 x 3hr practical |
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Assessment | Vibrations assignment (10%)|Internal test (20%)|Lab experiments (30%)|Final exam (40%) |
Timetable | View the lecture timetable | View the full unit timetable |
Textbooks
Required |
Beer FP, Johnston ER Jr, and Eisenberg ER, Vector Mechanics for Engineers, Dynamics, 12th Edition, McGraw-Hill, 2019. |
Links | Booktopia textbook finder |
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The University reserves the right to amend or remove courses and unit availabilities, as appropriate.