- Length 2 year full-time
- Minimum 96 Units
- Academic plan NENRE
- CRICOS code 077326G
- UAC code
Field of Education
- Environmental Engineering
The Master of Engineering in Renewable Energy requires the completion of 96 units, which must consist of:
72 units from completion of the following compulsory courses:
ENGN6250 Professional Practice 1
ENGN8260 Professional Practice 2
ENGN8100 Introduction to Systems Engineering
ENGN8120 Systems Modelling
ENGN8170 Group Project
ENGN6524 Photovoltaic Technologies
ENGN6516 Energy Resources and Renewable Technologies
ENGN8830 Photovoltaic Power Plants
ENGN8831 Integration of Renewable Energy into Power Systems and Microgrids
ENGN8832 Urban Energy and Energy Efficiency
ENGN8833 Industrial Energy Efficiency and Decarbonisation
A minimum of 12 units from completion of courses from the following list:
ENGN6224 Fluid Mechanics and Heat Transfer
ENGN6525 Solar Thermal Technologies
PHYS6301 Wind Energy
A maximum of 12 units from completion of elective courses offered by ANU
A Bachelor of Engineering, Bachelor of Engineering with Honours or international equivalent with a minimum GPA of 5/7.
Electrical Engineering, Electronic Engineering, Photovoltaic/Renewable Energy Engineering, Power Engineering, Mechanical Engineering
- Annual indicative fee for domestic students
For more information see: http://www.anu.edu.au/students/program-administration/costs-fees
- Annual indicative fee for international students
For further information on International Tuition Fees see: https://www.anu.edu.au/students/program-administration/fees-payments/international-tuition-fees
ANU offers a wide range of scholarships to students to assist with the cost of their studies.
Eligibility to apply for ANU scholarships varies depending on the specifics of the scholarship and can be categorised by the type of student you are. Specific scholarship application process information is included in the relevant scholarship listing.
For further information see the Scholarships website.
This two-year master qualification provides students with specialised knowledge and professional engineering skills to prepare them for a career in the rapidly-growing renewable energy industry. The program builds on ANU’s interdisciplinary engineering focus and research expertise to give students the skills to address complex multi-disciplinary problems, while at the same time providing advanced technical knowledge in renewable energy.
The program includes specialised courses in solar, wind and other renewable technologies, utility-scale systems design, grid integration and energy efficiency. Students also have the opportunity to select electives from across the University, including courses in the complementary areas of energy policy, law and economics.
Work Integrated Learning is an important part of the program and is delivered through the group project.
Graduates from ANU have been rated as Australia's most employable graduates and among the most sought after by employers worldwide.
The latest Global Employability University Ranking, published by the Times Higher Education, rated ANU as Australia's top university for getting a job for the fourth year in a row.
This program is available for applications to commence from First Semester, 2017
Upon successful completion, students will have the skills and knowledge to:
1. Professionally apply systematic engineering methods to address complex, multi-disciplinary real-world engineering problems related to generation, transmission and utilization of renewable energy.
2. Proficiently apply advanced, integrated technical knowledge in renewable energy and the underpinning sciences and scientific methods.
3. Identify and critically evaluate current developments and emerging trends within the renewable energy sector.
4. Contextualise renewable technology projects within a local, national and international framework, and consider social, ethical and environmental impacts and consequences.
5. Communicate effectively with colleagues, other engineering professionals and the broader community employing a range of communication media and tools.
6. Engage in independent investigation, critical reflection and lifelong learning to continue to practice at the forefront of the discipline.
7. Work effectively and proactively within cross-cultural, multi-disciplinary teams, demonstrating autonomy, ethical conduct, expert judgement, adaptability and responsibility to achieve engineering outcomes at a high standard.