Hobart
Introduction
The aim of this unit is to provide students expertise in the analysis of power system dynamics and stability for practical applications. The unit covers an introduction to the concept of power system stability, representation of synchronous machines and AC transmission modelling in stability studies, static and dynamic load models, steam and hydro turbines and governing systems, HVDC systems and their representation in stability studies, small-signal stability concept, eigenvalues and eigenvectors, small-signal stability of a single machine and multimachine systems, transient stability concept, simulation of power system dynamic response, direct method of transient stability analysis, voltage stability and voltage collapse, wide-area monitoring, and impact of wind and solar integration on power system dynamics.
Summary 2021
Unit name | Power System Dynamics and Stability |
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Unit code | ENG441 |
Credit points | 12.5 |
Faculty/School | College of Sciences and Engineering School of Engineering |
Discipline | Engineering |
Coordinator | Michael Negnevitsky |
Available as student elective? | No |
Breadth Unit? | No |
Availability
Note
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TNE Program units special approval requirements.
* 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 (see withdrawal dates explained for more information).
Learning Outcomes
1 | Determine small-signal stability of power systems using eigenvalues and eigenvectors |
2 | Evaluate power system dynamic response using appropriate commercial software |
3 | Determine transient stability of a power system using the equal area criterion |
4 | Investigate voltage stability and conditions for voltage collapse |
5 | Analyse the impact of renewable energy integration by simulating power system dynamics |
Fees
Requisites
Prerequisites
ENG333 Power Systems 1
Teaching
Teaching Pattern | 1 x 120 minute lecture weekly, 1 x 120 minute tutorial weekly, 6 x 180 minute practicals |
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Assessment | ATT1 - Two tests (10%) ATT2 - Project report (20-pages) and presentation (50% ATT3 - Exam (40%) |
Timetable | View the lecture timetable | View the full unit timetable |
Textbooks
Required | None |
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