Overview
On the satisfactory completion of this unit, you will be able to work both individually and in-team to model, analyse and investigate design and operation options for electrical power networks to meet community service requirements. You will be able to analyse the steady-state performance of power systems, perform both symmetrical and unsymmetrical fault calculations, and conduct stability analysis of power systems. You will be using the power systems simulation software Power World Simulator or equivalent to simulate different scenarios in the power network. As such, you will articulate the process of updating and maintaining power network assets to meet most safety, reliability, and quality requirements for both present and future.
Details
Pre-requisites or Co-requisites
ENEE12015 Electrical Power Engineering.
Important note: Students enrolled in a subsequent unit who failed their pre-requisite unit, should drop the subsequent unit before the census date or within 10 working days of Fail grade notification. Students who do not drop the unit in this timeframe cannot later drop the unit without academic and financial liability. See details in the Assessment Policy and Procedure (Higher Education Coursework).
Offerings For Term 2 - 2022
Attendance Requirements
All on-campus students are expected to attend scheduled classes – in some units, these classes are identified as a mandatory (pass/fail) component and attendance is compulsory. International students, on a student visa, must maintain a full time study load and meet both attendance and academic progress requirements in each study period (satisfactory attendance for International students is defined as maintaining at least an 80% attendance record).
Recommended Student Time Commitment
Each 6-credit Undergraduate unit at CQUniversity requires an overall time commitment of an average of 12.5 hours of study per week, making a total of 150 hours for the unit.
Class Timetable
Assessment Overview
Assessment Grading
This is a graded unit: your overall grade will be calculated from the marks or grades for each assessment task, based on the relative weightings shown in the table above. You must obtain an overall mark for the unit of at least 50%, or an overall grade of ‘pass’ in order to pass the unit. If any ‘pass/fail’ tasks are shown in the table above they must also be completed successfully (‘pass’ grade). You must also meet any minimum mark requirements specified for a particular assessment task, as detailed in the ‘assessment task’ section (note that in some instances, the minimum mark for a task may be greater than 50%). Consult the University’s Grades and Results Policy for more details of interim results and final grades.
All University policies are available on the CQUniversity Policy site.
You may wish to view these policies:
- Grades and Results Policy
- Assessment Policy and Procedure (Higher Education Coursework)
- Review of Grade Procedure
- Student Academic Integrity Policy and Procedure
- Monitoring Academic Progress (MAP) Policy and Procedure – Domestic Students
- Monitoring Academic Progress (MAP) Policy and Procedure – International Students
- Student Refund and Credit Balance Policy and Procedure
- Student Feedback – Compliments and Complaints Policy and Procedure
- Information and Communications Technology Acceptable Use Policy and Procedure
This list is not an exhaustive list of all University policies. The full list of University policies are available on the CQUniversity Policy site.
Feedback, Recommendations and Responses
Every unit is reviewed for enhancement each year. At the most recent review, the following staff and student feedback items were identified and recommendations were made.
Feedback from Student feedback
Students appreciated the lecture content to be assisting the tutorial questions
Continue this good practice
Feedback from Self reflection/Student Feedback
Poor quality of tutorial materials
Update the tutorial material
Feedback from Student Feedback
The students expected project problems to be released earlier in the term
Release the problems for the project activity earlier in the term
Feedback from Self reflection
Lack of good quality presentation slides for the lectures
Improve the slides by embedding some simulation results.
- Calculate fault currents under different scenarios and discuss the selection of appropriate protection schemes
- Solve power flow problems and appreciate the relevance of such studies in power system planning and operation
- Analyse power system performance in both balanced and unbalanced modes of operation by using appropriate software packages
- Investigate power angle stability for both single-machine and multimachine power systems
- Work both collaboratively and autonomously to analyse and solve problems
- Communicate effectively using power systems terminology, symbols and diagrams to present design documents, solutions, and calculations.
The Learning Outcomes for this unit are linked with the Engineers Australia Stage 1 Competency Standards for Professional Engineers in the areas of 1. Knowledge and Skill Base, 2. Engineering Application Ability and 3. Professional and Personal Attributes at the following levels:
Intermediate
Advanced
Refer to the Engineering Undergraduate Course Moodle site for further information on the Engineers Australia's Stage 1 Competency Standard for Professional Engineers and course level mapping information
Alignment of Assessment Tasks to Learning Outcomes
Assessment Tasks | Learning Outcomes | |||||
---|---|---|---|---|---|---|
1 | 2 | 3 | 4 | 5 | 6 | |
1 - Project (applied) - 15% | ||||||
2 - Written Assessment - 30% | ||||||
3 - Online Quiz(zes) - 20% | ||||||
4 - Online Test - 35% |
Alignment of Graduate Attributes to Learning Outcomes
Graduate Attributes | Learning Outcomes | |||||
---|---|---|---|---|---|---|
1 | 2 | 3 | 4 | 5 | 6 | |
1 - Communication | ||||||
2 - Problem Solving | ||||||
3 - Critical Thinking | ||||||
4 - Information Literacy | ||||||
5 - Team Work | ||||||
6 - Information Technology Competence | ||||||
7 - Cross Cultural Competence | ||||||
8 - Ethical practice | ||||||
9 - Social Innovation | ||||||
10 - Aboriginal and Torres Strait Islander Cultures |
Textbooks
Power System Analysis and Design
Edition: 6th edn (2016)
Authors: J. Duncan Glover, Thomas Overbye, and Mulukutla Sarma
CENGAGE Learning
Boston Boston , MA , USA
ISBN: 9781305636187
Binding: Paperback
IT Resources
- CQUniversity Student Email
- Internet
- Unit Website (Moodle)
- Access to a document scanner and a pdf converter
- Computer with Windows OS, headphones & microphone
- The free version of PowerWorld Simulator - downloadable from the internet
All submissions for this unit must use the referencing style: Harvard (author-date)
For further information, see the Assessment Tasks.
s.alahakoon@cqu.edu.au
Module/Topic
Introduction to power systems analysis
Chapter
Chapters1 & 2 of Glover, Sarma, and Overbye
Events and Submissions/Topic
Module/Topic
Introduction to Power System Modelling
Chapter
Chapters 3 & 4 of Glover, Sarma, and Overbye
Events and Submissions/Topic
Module/Topic
Symmetrical Components
Chapter
Chapter 8 of Glover, Sarma, and Overbye
Events and Submissions/Topic
Module/Topic
Fault Analysis
Chapter
Chapter 8&9 of Glover, Sarma, and Overbye
Events and Submissions/Topic
Module/Topic
Modelling of Power System Networks
Chapter
Chapter 5 of Glover, Sarma, and Overbye
Events and Submissions/Topic
Module/Topic
Chapter
Events and Submissions/Topic
Module/Topic
Introduction to Load Flow Analysis
Chapter
Chapter 6 of Glover, Sarma, and Overbye
Events and Submissions/Topic
Module/Topic
Load Flow Algorithms
Chapter
Chapter 6 of Glover, Sarma, and Overbye
Events and Submissions/Topic
Module/Topic
Load Flow Studies, Modelling and Voltage Control
Chapter
Chapter 6 of Glover, Sarma, and Overbye
Events and Submissions/Topic
Module/Topic
Introduction to Transient Stability
Chapter
Chapter 11 of Glover, Sarma, and Overbye
Events and Submissions/Topic
Module/Topic
Multi-machine systems, small-signal stability
Chapter
Chapter 11 of Glover, Sarma, and Overbye
Events and Submissions/Topic
Module/Topic
Stability controls, modelling of renewables
Chapter
Chapters 11 and 12 of Glover, Sarma, and Overbye
Events and Submissions/Topic
Module/Topic
Revision
Chapter
Events and Submissions/Topic
PROJECT Due: Week 12 Friday (7 Oct 2022) 11:59 pm AEST
Module/Topic
Chapter
Events and Submissions/Topic
End of Term Online Test may be scheduled in Week 13 (REVIEW/EXAM WEEK) or Week 14 (EXAM WEEK)
Module/Topic
Chapter
Events and Submissions/Topic
1 Project (applied)
- This assignment may contain 3-4 problems that will require the theoretical knowledge gained through your learning during the first five weeks.
- The topics covered in this assignment will be symmetrical components, balanced and unbalanced fault analysis, and transmission line modelling.
- The marking scheme for each question will be published with the assignment.
- Assignment questions will be available in the unit Moodle site in due course. Please also refer to the assessment criteria for more details.
Week 6 Friday (26 Aug 2022) 11:59 pm AEST
Submit to the link in the Assessment tile of the unit website in Moodle as a PDF file.
Week 8 Friday (9 Sept 2022)
Feedback sheet will be provided through unit website in Moodle.
A total of 100 marks is allocated to this assignment which will be scaled down to 15% of the unit total.
Students are assessed on the accuracy of calculated results, the correctness of the method used and the presentation.
- Calculate fault currents under different scenarios and discuss the selection of appropriate protection schemes
- Analyse power system performance in both balanced and unbalanced modes of operation by using appropriate software packages
- Work both collaboratively and autonomously to analyse and solve problems
- Communicate effectively using power systems terminology, symbols and diagrams to present design documents, solutions, and calculations.
2 Online Quiz(zes)
This is an online test covering week 6 up to week 9 lectures.
Week 12 Monday (3 Oct 2022) 11:45 pm AEST
Lecture time
Exam Week Monday (17 Oct 2022)
Feedback will be given through unit website in Moodle.
- A total of 100 marks is allocated to this test.
- Students are assessed on the accuracy of calculated results and the correctness of the method used.
- Investigate power angle stability for both single-machine and multimachine power systems
3 Written Assessment
- This assessment item will address most of this unit's learning outcomes and contribute to 30% of the final mark.
- Students will form teams of no more than three members for this assessment.
- Each team will be assigned a power system modelling and simulation exercise related to power systems stability, fault calculations, load flow etc.
- The project will be based on the free edition of PowerWorld Simulator. In this unit, you will achieve a basic competency in the use of PowerWorld Simulator. Video tutorials on the use of this software and instructions on installation are available on Moodle
Week 12 Friday (7 Oct 2022) 11:59 pm AEST
Submit the report as a PDF file to the link in the Assessment tile of the unit website in Moodle together with relevant simulation files.
Exam Week Friday (21 Oct 2022)
Feedback will be given through unit website in Moodle.
- Correct procedure and steps towards constructing necessary models using modelling and simulation exercise: 60%
- Correct answers and units: 30%
- Professional presentation and layout of the report: 10%
- More details on mark break down is available in Moodle.
- Solve power flow problems and appreciate the relevance of such studies in power system planning and operation
- Analyse power system performance in both balanced and unbalanced modes of operation by using appropriate software packages
- Work both collaboratively and autonomously to analyse and solve problems
- Communicate effectively using power systems terminology, symbols and diagrams to present design documents, solutions, and calculations.
4 Online Test
This online test may cover all topics from weeks 1 to 12 and may consist of a mix 4-6 numerical as well as descriptive answer questions.
This online test will be held during the University exam period (Week 13 or 14). The exact date and time will be confirmed by the end of week 9. This online test has a duration of 3 hrs. You will be provided with an additional 30 minutes to read the paper and to scan and upload the answer scripts. The Moodle submission link will become inactive 3.5 hrs after the start time. You are encouraged to sit the test from a location with a good Internet connection and where you have access to a scanner. If you are unable to find a scanner, you can use your mobile phone to scan and upload the answer scripts. Please find a list of Camera Scan apps below that is suitable for this.
1. Adobe Scan (DC) https://adobescan.app.link/d/1n1NntFHTkb
2. Microsoft Lens https://apps.apple.com/au/app/microsoft-lens-pdf-scanner/id975925059
3. SwiftScan https://swiftscan.app/en/index.html
4. CamScanner https://www.camscanner.com/
5. ClearScan https://clearscanapp.com/
Submitted through unit Moodle site as a PDF file.
No Assessment Criteria
- Calculate fault currents under different scenarios and discuss the selection of appropriate protection schemes
- Solve power flow problems and appreciate the relevance of such studies in power system planning and operation
- Investigate power angle stability for both single-machine and multimachine power systems
- Communicate effectively using power systems terminology, symbols and diagrams to present design documents, solutions, and calculations.
As a CQUniversity student you are expected to act honestly in all aspects of your academic work.
Any assessable work undertaken or submitted for review or assessment must be your own work. Assessable work is any type of work you do to meet the assessment requirements in the unit, including draft work submitted for review and feedback and final work to be assessed.
When you use the ideas, words or data of others in your assessment, you must thoroughly and clearly acknowledge the source of this information by using the correct referencing style for your unit. Using others’ work without proper acknowledgement may be considered a form of intellectual dishonesty.
Participating honestly, respectfully, responsibly, and fairly in your university study ensures the CQUniversity qualification you earn will be valued as a true indication of your individual academic achievement and will continue to receive the respect and recognition it deserves.
As a student, you are responsible for reading and following CQUniversity’s policies, including the Student Academic Integrity Policy and Procedure. This policy sets out CQUniversity’s expectations of you to act with integrity, examples of academic integrity breaches to avoid, the processes used to address alleged breaches of academic integrity, and potential penalties.
What is a breach of academic integrity?
A breach of academic integrity includes but is not limited to plagiarism, self-plagiarism, collusion, cheating, contract cheating, and academic misconduct. The Student Academic Integrity Policy and Procedure defines what these terms mean and gives examples.
Why is academic integrity important?
A breach of academic integrity may result in one or more penalties, including suspension or even expulsion from the University. It can also have negative implications for student visas and future enrolment at CQUniversity or elsewhere. Students who engage in contract cheating also risk being blackmailed by contract cheating services.
Where can I get assistance?
For academic advice and guidance, the Academic Learning Centre (ALC) can support you in becoming confident in completing assessments with integrity and of high standard.