Master of Engineering (Mechanical Engineering)
Royal Melbourne Institute of Technology
About
The main objective of the Master of Engineering (Mechanical Engineering) program is to develop advanced knowledge and skills in mechanical engineering that will enhance your career prospects in the relevant industries.
The program aims to provide you with skills to step up as project leaders, consultants and managers with the knowledge and skills to lead the introduction of new technologies and operating practices in process manufacturing oriented businesses.You will gain state of the art knowledge and skills in mechanical engineering and related technologies, combined with advanced oral and written communication, teamwork, design, project management and research skills.At the completion of the program you will be equipped to further your career aspirations in mechanical engineering, operations, or consultancy in manufacturing, automotive, petrochemical, construction, mineral processing, bio-processing, etc.
as:R&D leader introducing new technologies and research and development Team Leader implementing operational strategies Operations Manager responsible for the competitive performance of a unit Consultant providing specialist technical advice to industry.In this program you will undertake a capstone project with the 48 credit point course OENG1088 Masters Research Project (or the alternative of taking both of the 24 credit point courses OENG1089, Masters Research Project Part 1 and OENG1090, Masters Research Project Part 2).
In this project you will consolidate and expand the knowledge gained throughout the program through an in-depth experimental and/or analytical study of a highly technical and/or engineering management application.This program is primarily delivered in face-to-face mode at the City Campus.
Structure
Year One of Program
Complete the following Eight (8) Courses:
| Course Title | Credit Points | Course Code | Campus |
|---|---|---|---|
| Sustainable Engineering Practice and Design | 12 | OENG1118 | City Campus |
| Innovation and Technology Management | 12 | OENG1115 | City Campus |
| Risk and Project Management | 12 | OENG1117 | City Campus |
| Modelling and Simulation of Engineering Systems | 12 | OENG1116 | City Campus |
| Advanced CAE | 12 | MIET2491 | City Campus |
| Advanced Thermo Fluids | 12 | MIET2489 | City Campus |
| Advanced Dynamics | 12 | MIET2487 | City Campus |
| Advanced Mechanics of Solids | 12 | MIET2490 | City Campus |
Year Two of Program
Complete the following Three (3) Courses:
| Course Title | Credit Points | Course Code | Campus |
|---|---|---|---|
| Advanced Robotic Systems | 12 | MANU2453 | City Campus |
| Advanced Control Systems (PG) | 12 | EEET1368 | City Campus |
| Research Methods in Engineering | 12 | OENG1120 | City Campus |
Select and complete One (1) of the following Mechanical Option Courses:
| Course Title | Credit Points | Course Code | Campus |
|---|---|---|---|
| Sustainable Energy Systems and Design | 12 | MIET2129 | City Campus |
| Advanced Manufacturing Technologies | 12 | MANU2211 | City Campus |
| Advanced Heat Transfer | 12 | MIET2488 | City Campus |
| Advanced Mechatronics System Design | 12 | MANU2451 | City Campus |
| Professional Experience Postgraduate | 12 | EEET2471 | City Campus |
Complete the following One (1) Course:
| Course Title | Credit Points | Course Code | Campus |
|---|---|---|---|
| Master's Research Project | 48 | OENG1088 | City Campus |
Complete the following Two (2) Courses:
| Course Title | Credit Points | Course Code | Campus |
|---|---|---|---|
| Master's Research Project Part 1 | 24 | OENG1089 | City Campus |
| Master's Research Project Part 2 | 24 | OENG1090 | City Campus |
Entry requirements
Program Entry Requirements
Successful completion of an Australian bachelor degree (or international equivalent) in one of the following fields: Aerospace, Mechanical, Manufacturing, Mechatronics, Sustainable Systems or Automotive Engineering with a GPA of at least 2.0 out of 4.0. Applicants who have a successfully completed a relevant degree (as above) with a GPA of at least 1.5 out of 4.0, will be considered if they have at least 3 years of relevant industry experience.
OR Successful completion of an Australian postgraduate qualification (or international equivalent) in a related discipline (as above).
OR Applicants without any relevant prior qualification will be considered if they have at least 10 years of relevant industry experience.
International qualifications are assessed according to the Australian Qualifications Framework (AQF).
English Language Requirements
International applicants: A minimum IELTS (Academic module) overall score of 6.5, with no band below 6.0, or equivalent.
Local applicants with international qualifications: If your international bachelor degree was not taught in English you must undertake an IELTS test and achieve a score of 6.5 with no band less than 6.0, or equivalent.
For equivalents to English entry requirements, see the English equivalents web page.
Learning outcomes
Program Learning Outcomes*:
1. Needs, Context and Systems
- Describe, investigate and analyse complex engineering systems and associated issues (using systems thinking and modelling techniques)
- Exposit legal, social, economic, ethical and environmental interests, values, requirements and expectations of key stakeholders
- Identify and assess risks (including OH&S) as well as the economic, social and environmental impacts of engineering activities
2. Problem Solving and Design
- Develop creative and innovative solutions to engineering problems
- Anticipate the consequences of intended action or inaction and understand how the consequences are managed collectively by your organisation, project or team
- Develop and operate within a hazard and risk framework appropriate to engineering activities
3. Analysis
- Comprehend and apply advanced theory-based understanding of engineering fundamentals and specialist bodies of knowledge in the selected discipline area to predict the effect of engineering activities
- Apply underpinning natural, physical and engineering sciences, mathematics, statistics, computer and information sciences.
4. Professional Practice
- Initiate, plan, lead or manage engineering activities
- Understand the scope, principles, norms, accountabilities and bounds of contemporary engineering practice in the specific discipline
- Apply systematic approaches to the conduct and management of engineering projects
- Demonstrate effective team membership and team leadership
- Communicate in a variety of different ways to collaborate with other people, including accurate listening, reading and comprehension, based on dialogue when appropriate, taking into account the knowledge, expectations, requirements, interests, terminology and language of the intended audience
- Display a personal sense of responsibility for your work
- Demonstrate orderly management of self, and professional conduct.
5. Research
- Plan and execute a substantial research-based project, with creativity and initiative in new situations in professional practice and with a high level of personal autonomy and accountability
- Be aware of knowledge development and research directions within the engineering discipline.
- Develop creative and innovative solutions to engineering challenges
- Assess, acquire and apply the competencies and resources appropriate to engineering activities
- Demonstrate professional use and management of information.
- Acknowledge (clearly) your own contributions and the contributions from others and distinguish contributions you may have made as a result of discussions or collaboration with other people
*As a Masters program of two years full time duration, this program is designed to develop Stage 1 and Stage 2 Engineers Australia professional engineering competency requirements.
Institution
