Renewable energy engineering is in high demand globally as we find alternate methods of energy harvesting to meet our future energy needs and future proof our reliance on hydrocarbons as much as it is possible to do. Considerable innovation and improvements are continuous within this field as it is by no means at a stage where society can rely on it to fuel all needs. The sector is interdisciplinary and this programme provides you with a wide range of very useful skills and knowledge to problem solve and progress current renewables and work towards innovation whether that is in a renewables company or as a start up.
You study electrical and electronic engineering pertinent to smart grid, sensing energy use, developing energy harvesting techniques, and renewable energy exchange, plus ability to harvest energy from all of our natural resources including wind, solar, hydro, marine, geothermal, biomass and other newly developing areas.Renewables is definitely an employable sector as governments are now challenged by finite resources coming from traditional areas, climate change and societal concerns about how we harvest energy in the future and our ability to survive climatic issues, population increase and manage work and life.
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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Power Engineering and Sustainable Energy at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).
The Master's course in Power Engineering and Sustainable Energy places strong emphasis on state-of-the-art semiconductor devices and technologies, advanced power electronics and drives, and advanced power systems. The Power Engineering and Sustainable Energy course also covers conventional and renewable energy generation technologies. Exciting new developments such as wide band gap electronics, energy harvesting, solar cells and biofuels are discussed and recent developments in power electronics are highlighted.
The College of Engineering has an international reputation for electrical and electronics research for energy and advanced semiconductor materials and devices.
Greenhouse gas emission and, consequently, global warming are threatening the global economy and world as we know it. A non-rational use of electrical energy largely contributes to these.
Sustainable energy generation and utilisation is a vital industry in today’s energy thirsty world. Energy generation and conversion, in the most efficient way possible, is the key to reducing carbon emissions. It is an essential element of novel energy power generation system and future transportation systems. The core of an energy conversion system is the power electronics converter which in one hand ensures the maximum power capture from any energy source and on another hand controls the power quality delivered to grid. Therefore the converter parameters such as efficiency, reliability and costs are directly affecting the performance of an energy system.
Transmission and distribution systems will encounter many challenges in the near future. Decentralisation of generation and storage systems has emerged as a promising solution. Consequently, in the near future, a power grid will no longer be a mono-directional energy flow system but a bi-directional one, requiring a much more complex management.
The MSc in Power Engineering and Sustainable Energy is modular in structure. Students must obtain a total of 180 credits to qualify for the degree. This is made up of 120 credits in the taught element (Part One) and a project (Part Two) that is worth 60 credits and culminates in a written dissertation. Power Engineering and Sustainable Energy students must successfully complete Part One before being allowed to progress to Part Two.
Part-time Delivery mode
The part-time scheme is a version of the full-time equivalent MSc in Power Engineering and Sustainable Energy scheme, and as such it means lectures are spread right across each week and you may have lectures across every day. Due to this timetabling format, the College advises that the scheme is likely to suit individuals who are looking to combine this with other commitments (typically family/caring) and who are looking for a less than full-time study option.
Those candidates seeking to combine the part-time option with full-time work are unlikely to find the timetable suitable, unless their job is extremely flexible and local to the Bay Campus.
Modules on the MSc Power Engineering and Sustainable Energy course can vary each year but you could expect to study:
Advanced Power Electronics and Drives
Power Semiconductor Devices
Advanced Power Systems
Energy and Power Engineering Laboratory
Power Generation Systems
Modern Control Systems
Wide Band-Gap Electronics
Environmental Analysis and Legislation
Communication Skills for Research Engineers
The new home of MSc in Power Engineering and Sustainable Energy is at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.
Engineering at Swansea University has extensive IT facilities and provides extensive software licenses and packages to support teaching. In addition the University provides open access IT resources.
Our new WOLFSON Foundation funded Power Electronics and Power System (PEPS) laboratory well-appointed with the state-of the-art equipment supports student research projects.
Employment in growing renewable energy sector, power electronic and semiconductor sector, electric/hybrid vehicle industry.
The MSc Power Engineering and Sustainable Energy is for graduates who may want to extend their technical knowledge and for professional applicants be provided with fast-track career development. This MSc addresses the skills shortage within the power electronics for renewable energy sector.
BT, Siemens, Plessey, GE Lighting, Schlumberger, Cogsys, Morganite, Newbridge Networks, Alstom, City Technology, BNR Europe, Philips, SWALEC, DERA, BTG, X-Fab, ZETEX Diodes, IQE, IBM, TSMC, IR, Toyota, Hitachi.
As a student on the MSc Power Engineering and Sustainable Energy course, you will learn about numerical simulation techniques and have the opportunity to visit electronics industries with links to Swansea.
The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.
The REF assesses the quality of research in the UK Higher Education sector, assuring us of the standards we strive for.
The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.
Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.
With recent academic appointments strengthening electronics research at the College, the Electronic Systems Design Centre (ESDC) has been re-launched to support these activities.
The Centre aims to represent all major electronics research within the College and to promote the Electrical and Electronics Engineering degree.
Best known for its research in ground-breaking Power IC technology, the key technology for more energy efficient electronics, the Centre is also a world leader in semiconductor device modelling, FEM and compact modelling.
This one-year programme is designed to equip graduates and professionals with a broad and robust training on modern power engineering technologies, with a strong focus on renewable energy conversion and smart grids. It is suitable for recent graduates who wish to develop the specialist knowledge and skills relevant to this industry and is also suitable as advanced study in preparation for research work in an academic or industrial environment.
In semesters 1 and 2, the programmes comprises a mixture of taught courses, workshops and a group design project, led by leading experts in the field, covering the key topics in power systems, electrical machines and power electronics. The final part of the programme is an individual dissertation, which provides a good opportunity for students to apply their acquired skills to real problems in electrical power engineering.
This one year programme at the University of Edinburgh will immerse the students in the most current developments in the area of Electrical Power Engineering, through a combination of taught modules, workshops, a research dissertation, and a range of supporting activities delivered by internationally leading experts in the field. The programme develops through the year from advanced fundamental topics and research tools and techniques in electrical power engineering, to specialist courses on emerging technologies and advanced numerical methods for power engineering problems, and culminates in the summer dissertation project where the acquired skills in various areas are put into practice in application to an actual power engineering problem.
Topics covered within the individual courses of the programme, include (but are not limited to):
In addition, our MSc students actively engage in research as part of their dissertation projects either within the Institute for Energy Systems or with industry, with some joining our PhD community afterwards.
This programme is delivered over 12 months, with two semesters of taught courses, followed by a research project leading to the submission of a Master’s Thesis.
The above courses correspond to 120 credits of taught material, plus 60 credits of a research project.
The main objective of the programme is to train the next generation of electrical power engineers who:
Governments worldwide are putting in place plans to decarbonise and modernise their electricity sector. A transition to a green economy will require a highly skilled workforce led by electrical power engineers with a solid academic background, an appreciation of the trajectory of the industry and an understanding of the challenges and implications brought about by the introduction of new power technologies.
According to the Institution for Engineering & Technology (IET): “The business of managing and distributing power in the UK is beginning to undergo revolutionary changes and [power] engineers are the people who will play a pivotal role in keeping the lights on”. This also holds true in many other developed and developing countries in the world.
Power engineers are employed in public/governmental organisations as well as in the private sector and cover areas spanning from generation, to conversion and transmission of electrical power, design and manufacturing of power components and systems, and energy policy and commerce. In the UK, experienced, chartered power engineers can earn around £45,000 a year on average*.
The programme will run in a close association with other activities within the broader Electrical Engineering programme within the School, including networking events, industrial presentations and seminars. It will benefit from the current strong connections with industry (coordinated by the Student Industry Liaison Manager, and existing research associations and consortia (such as the EPSRC Centre for Energy Systems Integration).
The School of Mechanical, Aerospace and Civil Engineering has a strong and unique tradition in the UK in Aerospace Design, Helicopters, Heat Transfer, Aerodynamics, Computational Fluid Dynamics and Flow Diagnostics. This course builds on those strengths and exploits our links with BAe Systems, Airbus, Rolls-Royce, DSTL, USAF, North West Aerospace Alliance, North West Development Agency and SBAC.
This MSc aims to produce high quality graduates with specialist training in aerospace engineering who will be suitable for employment in the engineering industries and consultancies linked to that industry. Aerospace engineering graduates are highly valued and are currently in great demand and the Manchester programme specifically seeks to serve this growing industry requirement. The programme is suitable for engineering and science graduates, as well as engineering professionals working in technical and commercial management. The programme is also well designed to be used for conversion toAerospace Engineering from some close enough specialities such as Mechanics, Mathematics and Physics.
The Aerospace Engineering MSc is a full time course which is studied over 12 months and there is one start date each year in September. You will develop advanced technical skills in Aerospace Engineering that will enable you to pursue a career in both general and specialised engineering industries or develop an in depth knowledge for a career in research in industry or academia.
For further information about the course content, please see the example programme structure .
Practical support and advice for current students and applicants is available from the Disability Advisory and Support Service. Email: [email protected]
The Aerospace Engineering MSc has a strong focus on employability to support you to take control of your future and give yourself the best chance of securing your ideal job after graduation.
Each year Manchester careers fairs, workshops and presentations attract more than 600 exhibitors and 20,000 visitors to target Manchester graduates.
After graduating with an Aerospace Engineering MSc you will be in a strong position to seek employment with companies such as: Airbus, Rolls Royce, GE Aviation, Airbus, Bombardier Transportation, BAe Systems, MBDA, SAFRAN, GKN Aerospace, Spirit, Finmeccanica, EDF, BP, Schlumberger, etc.
The UK Aerospace Engineering is 2nd largest in the world and around 30% of companies in the Aerospace sector currently have vacancies.
Destination of Leavers Survey
Past graduates have found employment in:
Two highly established organisations, the Royal Aeronautical Society and Institution of Mechanical Engineers , have accredited the Aerospace Engineering MSc course under license from the UK regulator, the Engineering Council . This allows satisfactory completion of the Aerospace Engineering MSc to contribute towards the academic requirements for registration with these Institutions as a Chartered Engineer.
Mechanical engineering applies human and material resources to the design, construction, operation and maintenance of machines to move people, goods and materials, generate energy, produce goods and services, control pollution and dispose of wastes.
Mechanical engineers turn energy into power and motion, focusing on the generation, conversion and use of energy, as well as the design, construction and operation of devices and systems.
You will learn from world leaders in fluid mechanics, turbulence and biomechanics. Opportunities to consolidate theory with practice will come from group activities, site visits and industry projects. You will have access to well-equipped laboratories for materials testing, engine/turbine testing, wind tunnel investigations, simulation and metal forming processes. A heavy engineering workshop is available for the manufacture of testing facilities and research apparatus, as well as extensive computer facilities.
The Master of Engineering (Mechanical with Business) leads to a formal qualification in mechanical engineering at the Masters level.
The Master of Engineering (with Business) is designed to provide students with a formal qualification in engineering at the masters level, with a business specialisation that recognises the need for engineers to understand the management and workings of modern professional organisations.
Students who undertake the Master of Engineering (with Business) replace five advanced technical electives with five business subjects that have been tailored specifically for engineering students and co-developed with Melbourne Business School.
Graduates will have a grounding in financial, marketing and economic principles enabling them to work efficiently in any organisation, as well as the ability to apply the technical knowledge, creativity and team work skills learnt in their engineering training. This combination of knowledge and skills will be a powerful asset in the workplace.
Mechanical engineering not only interacts with all other disciplines of engineering, but increasingly with other disciplines such as medicine and biology, supported by sophisticated computer technology. You will develop a breadth of skills and depth of fundamental knowledge, which will open up a wide variety of possible career directions.
Career opportunities exist in a diverse range of industries from aeronautics, automotive, biomedical, manufacturing, construction and building to robotics and the environment. Emerging technologies in bioengineering, materials science, and nanotechnology will create further opportunities.
Our graduates are employed by companies such as AECOM, Alcoa, BP Australia, ExxonMobil, Orica Limited, Origin Energy, Bosch, Shell, Jacobs and OZ Minerals.
This Master of Engineering (with Business) degree is professionally recognised under two major accreditation frameworks — EUR-ACE® and the Washington Accord (through Engineers Australia). Graduates can work as chartered professional engineers throughout Europe, and as professional engineers in the 17 countries of the Washington Accord.