• Xi’an Jiaotong-Liverpool University Featured Masters Courses
  • University of York Featured Masters Courses
  • Regent’s University London Featured Masters Courses
  • University of Glasgow Featured Masters Courses
  • University of Edinburgh Featured Masters Courses
  • Leeds Beckett University Featured Masters Courses
  • University of Leeds Featured Masters Courses
  • Swansea University Featured Masters Courses
University of Southampton Featured Masters Courses
Cardiff University Featured Masters Courses
University of St Andrews Featured Masters Courses
Barcelona Executive Business School Featured Masters Courses
FindA University Ltd Featured Masters Courses
"power" AND "systems" AND…×
0 miles

Masters Degrees (Power Systems Engineering)

  • "power" AND "systems" AND "engineering" ×
  • clear all
Showing 1 to 15 of 331
Order by 
The Power Systems Engineering MSc is designed to provide students with the necessary knowledge and skills to work at a professional level in industries involved in the production, distribution and consumption of energy and power. Read more
The Power Systems Engineering MSc is designed to provide students with the necessary knowledge and skills to work at a professional level in industries involved in the production, distribution and consumption of energy and power. This wide range of industries includes transport, conventional and renewable power generation.

Degree information

Students study analysis and design of conventional and renewable machinery systems and the use of computers in their advanced engineering analysis. Students gain knowledge of electrical and mechanical engineering principles, quantitative methods, and mathematical and computer modelling alongside an awareness of the codes of practice, standards and quality issues within the modern industrial world. They also take modules in project management.

Students undertake modules to the value of 180 credits.

The programme consists of six core modules (90 credits), one optional module (15 credits) and a research project (75 credits).

Core modules
-Power Transmission and Auxiliary Machinery Systems
-Electrical Machines and Power Electronic Drives
-Electrical Power Systems and Electrical Propulsion
-New and Renewable Energy Systems
-Project Management
-Group Project

Optional modules
-Applied Thermodynamics and Turbomachinery
-Vibrations, Acoustics and Control
-Advanced Computer Applications in Engineering

Dissertation/report
All students undertake an independent research project which culminates in a project report and oral presentation. In many cases the work has some input from industry.

Teaching and learning
This dynamic programme is delivered through lectures, tutorials, individual and group projects, practical laboratory work and coursework assignments, (including computational analysis). Assessment is through written, oral and viva voce examinations and coursework (including the evaluation of laboratory reports, technical and project reports, problem-solving exercises, computational and modelling skills and oral presentations).

Careers

The Power Systems Engineering MSc has been accredited by the Engineering Council as meeting the further learning requirements, in full, for registration as a Chartered Engineer for a period of five years, from the 2012 student cohort intake onwards.

Top career destinations for this degree:
-Junior Project Manager, Pinnacle Developments Ltd
-Electrical Engineer, BP
-Traction Power Specialist, Mott MacDonald
-PhD High Power Engineering, University of Leicester
-Power Engineer, General Electric (GE)

Employability
Delivered by leading research and academic staff from across UCL, you will definitely have plenty of opportunities to network and keep abreast of emerging ideas through cross-fertilisation with collaborating companies and governmental bodies such as BAE Systems, Rolls Royce, Lloyds Register and TfL who provide specialised lectures and are key to our research success. We will encourage you to develop networks through the programme itself and via the department’s careers programme which includes employer-led events and individual coaching. We equip our graduates with the skills and confidence needed to play a creative and leading role in the professional and research community.

Why study this degree at UCL?

The department has an international reputation for the excellence of its research which is funded by numerous bodies including: EPSRC, EU, Wellcome Trust, the Royal Society, the Leverhulme Trust, UK Ministry of Defence, BAe Systems, Cosworth Technology, Ebara, Jaguar Cars, Shell, and BP.

The Power Systems Engineering MSc is accredited under UK-SPEC by the Institution of Mechanical Engineers (IMechE), Institute of Engineering and Technology (IET), and the Institute of Marine Engineering Science and Technology (IMarEST). This programme also constitutes in part the requirement to obtain Chartered Engineering status.

UCL Mechanical Engineering has seen, in recent years, unprecedented activity in refurbishing and re-equipping our laboratories. Highlights of this include an extensive workshop, four engine test cells of the highest specification, a fuel cell laboratory, an electrical power laboratory and a new fluid mechanics laboratory.

Read less
Electricity is playing an increasing role as we look to develop low carbon sources of energy. The design of electrical power systems is becoming increasingly complex, to manage intermittent sources of generation, and increased levels of demand from new types of load such as electric vehicles. Read more
Electricity is playing an increasing role as we look to develop low carbon sources of energy. The design of electrical power systems is becoming increasingly complex, to manage intermittent sources of generation, and increased levels of demand from new types of load such as electric vehicles.

The Distance Learning MSc in Electrical Power Systems Engineering allows engineers working in the sector to enhance their skills. It provides them with the tools and techniques to keep pace with the rapidly evolving electricity industry. The course covers the latest developments in the electricity industry and delivers up-to-date training in all aspects of electrical power systems.

Aims

The course will develop your understanding of how these future electrical networks will be designed and operated. It will provide you with a solid understanding of the characteristics of components such as generators, lines, cables, transformers and power electronics devices. It will provide you with the skills you need to carry out power flow and fault calculations, learning how these techniques are used to study the behaviour of large systems. The course also covers a range of other topics such as HVDC, how renewable generation is integrated into a power system, the increasing importance of smart grids, and how to assess and remedy power quality problems.The course is based on the long-running MSc in Electrical Power Systems Engineering delivered by The University of Manchester. On graduation you will be a member of a network of global alumni, many in senior positions in the electricity supply industry.

The course has been designed to support those working in industry. Multiple entry points exist and the course can be completed in a timescale that suits your needs. Your dissertation project will ideally be based on a problem you and your company need to resolve, ensuring the programme delivers value for both you and your employer.

Read less
Engineers are the key to the development of society and solving the problems the world currently faces. They have the power to make the world fundamentally different. Read more
Engineers are the key to the development of society and solving the problems the world currently faces. They have the power to make the world fundamentally different.

The Master of Advanced Engineering is the key transitional stage in your career, transforming you into a global leader. Gain a depth of knowledge, mastering the crucial skills to become a leading contributor in your field.

Customise your degree - the Master of Advanced Engineering offers flexibility to complete your Master degree in just one year, or you can choose a two year option.

This course is designed to extend your knowledge in your chosen specialisation area and advance your leadership and complex problem-solving skills in a cross cultural environment.

Understand, reflect critically upon and apply methods in at least one specialist engineering area to design solutions to complex, multifaceted engineering problems.

Common core units will develop crucial skills in areas such as data analysis and entrepreneurship, translating theory into engineering practice. In discipline core units you will identify, interpret and critically appraise current developments and technologies within your specialisation.

Enhancement units are designed to provide breadth and are taken from either another engineering specialisation or in complementary areas such as information technology and business.

In addition, the two year version of the program offers a range of technical electives that will deepen your understanding of a specific topic, and two, year- long engineering project units. You will work closely with an academic on a topic of your choice and immerse yourself in a multidisciplinary design project.

The Master of Advanced Engineering could also be your stepping stone to a research degree. All of this in highly interactive, expert led classes.

Visit the website http://www.study.monash/courses/find-a-course/2016/advanced-engineering-e6001?domestic=true

Overview

Please select a specialisation for more details:

Chemical engineering

Your qualification will be a Master of Advanced Chemical Engineering

Please note that this specialisation is available only in Clayton.

The Master of Advanced Chemical Engineering allows you to engage in the areas of study including advanced reaction engineering, process design and optimization, conversion of bioresources into fuel, materials and specialty chemicals, and nanostructured membranes for sustainable separations and energy production with an emphasis on the latest developments in the field. In this course, you will develop specialised knowledge and skills that are important to Chemical Engineers in industry and research. This course provides graduates with enhanced opportunities for advancement in their careers.

Civil engineering (Infrastructure systems)

Your qualification will be a Master of Advanced Civil Engineering (Infrastructure Systems)

The Master of Advanced Civil Engineering (Infrastructure Systems) will equip graduates to work with in the area of infrastructure engineering and management. It will provide the fundamental knowledge associated with interfacing both structural and geotechnical designs for infrastructure systems. The program is designed to equip you with advanced skills necessary for managing the challenges posed by ageing and leading designs of new complex infrastructure systems. The course is suitable for new graduates, professionals and managers who are keen to upgrade their existing design and management skills, as well as to develop theoretical and applied knowledge in the area of infrastructure engineering and management.

Civil engineering (Transport)

Your qualification will be a Master of Advanced Civil Engineering (Transport)

Please note that this specialisation is available only in Clayton.

The Master of Advanced Civil Engineering (Transport) program deals with the fundamental knowledge associated with transport engineering and management, traffic engineering, intelligent transport systems and transport planning. The program in is a response to the growing need for engineers with broad awareness of the characteristics and significance of transport, including its technological, economic and social impact. At the same time, the program outlines the state-of-the-art of transport engineering, as it may be applied to the solution of real problems in the planning, design, management and operation of transport facilities. The course is suitable for new graduates, professionals and managers who are keen to upgrade their existing design and management skills as well as to develop theoretical and applied knowledge in the area of transport engineering and management.

Civil engineering (Water)

Your qualification will be a Master of Advanced Civil Engineering (Water)

Please note that this specialisation is available only in Clayton.

The Master of Advanced Civil Engineering (Water) allows you to major in water resources engineering and management. This program deals with the fundamental knowledge associated with surface and ground water flow, stormwater management, water quality, flood forecasting and mitigation. The program is designed to equip you with advanced skills necessary for managing the challenges posed by changing climatic condition on water resource management. The course is suitable for new graduates, professionals and managers who are keen to upgrade their existing design and management skills as well as to develop theoretical and applied knowledge in the area of water resources engineering and management.

Electrical engineering

Your qualification will be a Master of Advanced Electrical Engineering

Please note that this specialisation is available only in Clayton.

The Master of Advanced Electrical Engineering will give you a broad introduction to advanced techniques in signal processing, communications, digital systems and electronics. The units have been chosen around the common theme of embedded systems: special purpose computing systems designed for specific applications. They are found just about everywhere including in consumer electronics, transportation systems, medical equipment and sensor networks. The course will mix theory and practice and will contain a significant amount of hands-on learning in laboratories and team-based design projects.

Energy and sustainability engineering

Your qualification will be a Master of Advanced Engineering (Energy and Sustainability)

Please note that this specialisation is available only in Malaysia.

The Master of Advanced Engineering (Energy and Sustainability) is designed for qualified engineers keen to deepen their knowledge in the energy and sustainability area. The course provides foundations in general engineering through engineering analysis and entrepreneurship units. Students can major in this program by examining energy and sustainability area from a multi-disciplinary perspective. Students can also choose elective units such as environment and air pollution control and smart grids to further enhance their knowledge in this area or undertake a minor research work to pursue a topic of interest related to this area.

Materials engineering

Your qualification will be a Master of Advanced Materials Engineering

Please note that this specialisation is available only in Clayton.

The Master of Advanced Materials Engineering encompasses practical aspects of the key classes of materials such as metals, polymers, biomaterials, nanomaterials and energy-related materials. This program particularly focuses on the most up-to-date aspects of the field, along with the utilisation of materials and their electronic, chemical and mechanical properties as underpinned by the microstructures that are revealed by modern characterisation techniques. This program is designed to prepare students to appreciate and exploit the central role of materials in addressing the present technical, economic and environmental problems involved in the design and construction of engineering structures, processes and devices. This course is ideally suited for new graduates as well as professional engineers who are eager to advance their applied knowledge in the area of Materials Engineering.

Mechanical engineering

Your qualification will be a Master of Advanced Mechanical Engineering

Please note that this specialisation is available only in Clayton.

Most modern engineering projects are multidisciplinary in nature and require a broad range of skills, proficiencies and perspectives to accomplish the task. The Master of Advanced Mechanical Engineering takes a systems approach to the design, monitoring and performance of complex mechanical engineering systems in the fields of renewable energy, aerospace, buildings, transportation, and biomedical devices. The systems approach also permeates the design of the course: four discipline-based core units are vertically integrated so that common problems are examined from different perspectives, culminating in a sustainable systems unit.

For more information visit the faculty website - http://www.study.monash/media/links/faculty-websites/engineering

Find out how to apply here - http://www.study.monash/courses/find-a-course/2016/advanced-engineering-e6001?domestic=true#making-the-application

Read less
Take advantage of one of our 100 Master’s Scholarships to study Power Engineering and Sustainable Energy at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Power Engineering and Sustainable Energy at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

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.

Key Features of MSc in Power Engineering and Sustainable Energy

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

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
Optimisation

Facilities

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.

Careers

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.

Links with industry

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.

Research

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.

World-Leading Research

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.

Read less
Power system engineering is about keeping things in balance. Not just the balance between generation and load or between production and consumption of reactive power. Read more
Power system engineering is about keeping things in balance. Not just the balance between generation and load or between production and consumption of reactive power. It is also about the balance between the cost of energy and its environmental impact or the balance between the reliability of the supply and the investments needed to develop the system. These programmes will teach you how to quantify both sides of these equations and then how to improve the balances through technological advances and the implementation of sophisticated computing techniques.

During the second semester the course units explore in more depth the 'operation' and the 'plant' aspects of power systems. For example, you will study how renewable generation is integrated in a power system or how to assess and remedy power quality problems.

During the summer, your MSc dissertation project gives you a chance to develop your research skills and to explore in depth one of the topics discussed during the course.

Aims

-Provide an advanced education in electrical power engineering.
-Give graduates the education, the knowledge and the skills they need to make sound decisions in a rapidly changing electricity supply industry.
-Give a sound understanding of the principles and techniques of electrical power engineering.
-Give a broad knowledge of the issues and problems faced by electrical power engineers.
-Give a solid working knowledge of the techniques used to solve these problems.

Coursework and assessment

You are required to take seven examinations. In addition, course work (eg lab reports) accounts for typically 20% of the mark for each course unit. One course units is assessed on the basis of course work only. The summer research project is assessed on the basis of a dissertation of about 50 pages.

Career opportunities

Over the last thirty years, hundreds of students from around the world have come to the University to obtain an MSc in Electrical Power Engineering or similar. After graduation, they went on to work for electric utilities, equipment manufacturers, specialised software houses, universities and consultancy companies.

Read less
Power system engineering is about keeping things in balance. Not just the balance between generation and load or between production and consumption of reactive power. Read more
Power system engineering is about keeping things in balance. Not just the balance between generation and load or between production and consumption of reactive power. It is also about the balance between the cost of energy and its environmental impact or the balance between the reliability of the supply and the investments needed to develop the system. This course will teach you how to quantify both sides of these equations and then how to improve the balances through technological advances and the implementation of sophisticated computing techniques.

In the first semester you learn how power systems are designed and operated. This involves studying not only the characteristics of the various components (generators, lines, cables, transformers and power electronics devices) but also how these components interact. Through lectures and computer based exercises you become familiar with power flow and fault calculations and you learn how the techniques used to study the behaviour of large systems. Experiments in our high voltage laboratory give you an appreciation for the challenges of insulation co-ordination.

During the second semester the course units explore in more depth the 'operation' and the 'plant' aspects of power systems. For example, you will study how renewable generation is integrated in a power system or how to assess and remedy power quality problems.

Prior to your summer break a preliminary study and the outline of your MSc dissertation project is completed, this is fully developed throughout the second year of the course. The yearlong enhanced individual research provides you great opportunities to develop advanced research skills and to explore in depth some of the topics discussed during the course. This includes training in research methods, and advanced simulation and experimental techniques in power systems and high voltage engineering as well as academic paper writing and poster and paper presentation.

Aims

-Provide an advanced education in electrical power engineering.
-Give graduates the education, the knowledge and the skills they need to make sound decisions in a rapidly changing electricity supply industry.
-Give a sound understanding of the principles and techniques of electrical power engineering.
-Give a broad knowledge of the issues and problems faced by electrical power engineers.
-Give a solid working knowledge of the techniques used to solve these problems.
-Educate students with advanced research skills necessary to address current and future technological advancements.

Coursework and assessment

You are required to take seven examinations. In addition, course work (eg lab reports) accounts for typically 20% of the mark for each course unit. One course units is assessed on the basis of coursework only.

The enhanced research project is assessed on the basis of a research poster, an extended abstract, a research papers and a dissertation of about 70 pages.

Course unit details

Course units typically include:
-Electrical Power Fundamentals
-Analysis of Electrical Power and Energy Conversion Systems
-Power System Plant, Asset Management and Condition Monitoring
-Power System Operation and Economics
-Power System Dynamics and Quality of Supply
-Power System Protection
-Smart Grids and Sustainable Electricity Systems
-Techniques for Research and Industry

Career opportunities

Over the last thirty years, hundreds of students from around the world have come to the University to obtain an MSc in Electrical Power Engineering or similar. After graduation, they went on to work for electric utilities, equipment manufacturers, specialised software houses, universities and consultancy companies.

This course also provides the students with additional research skills necessary for starting a PhD degree or entering an industrial research and development career.

Read less
EIT is pleased to bring you the Master of Engineering (Electrical Systems)** program. IN THIS ACCREDITED AND PRESTIGIOUS PROGRAM YOU WILL GAIN. Read more
EIT is pleased to bring you the Master of Engineering (Electrical Systems)** program.

IN THIS ACCREDITED AND PRESTIGIOUS PROGRAM YOU WILL GAIN:
- Skills and know-how in the latest and developing technologies in electrical systems
- Practical guidance and feedback from experts from around the world
- Live knowledge from the extensive experience of expert instructors, rather than from just theoretical information gained from books and college
- Credibility and respect as the local electrical systems expert in your firm
- Global networking contacts in the industry
- Improved career choices and income
- A valuable and accredited Master of Engineering (Electrical Systems)** qualification

The next intake will start on the week of June 27, 2016.

Contact us to find out more and apply (http://www.eit.edu.au/course-enquiry).

** A note regarding recognition of this program in the Australian education system: EIT is the owner of this program. The qualification is officially accredited by the Tertiary Education Quality and Standards Agency (TEQSA). EIT delivers this program to students worldwide.

Visit the website http://www.eit.edu.au/master-engineering-electrical-systems

PROFESSIONAL RECOGNITION

This Master Degree (or Graduate Diploma) is officially accredited by the Tertiary Education Quality and Standards Agency (TEQSA) in Australia.

It is a professional development program and is not currently an entry-to-practice qualification. Engineers Australia are considering this and other programs for those students desiring professional status (e.g. CPEng). However, the outcome of this review may or may not result in a student gaining chartered professional status if he or she does not already possess this.

Additional Entry Requirements

An appropriate level of English Language Proficiency equivalent to an English pass level in an Australian Senior Certificate of Education, or an IELTS score of 6.5 (with no individual band less than 6.0) or equivalent as outlined in the EIT Admissions Policy.

Congruent field of practice means one of the following with adequate electrical engineering content (with fields not listed below to be considered by the Dean and the Admissions committee on a case-by-case basis):

• Electrical Engineering

• Electronic and Communication Systems

• Industrial Engineering

• Instrumentation, Control and Automation

• Mechatronic Systems

• Manufacturing and Management Systems

• Industrial Automation

• Production Engineering

Overview

Electrical power is an essential infrastructure of our society. Adequate and uninterrupted supply of electrical power of the required quality is essential for industries, commercial establishments and residences; and almost any type of human activity is impossible without the use of electricity. The ever-increasing cost of fuels required for power generation, restricted availability in many parts of the world, demand for electricity fueled by industrial growth and shortage of skilled engineers to design, operate and maintain power network components are problems felt everywhere today. The Master of Engineering (Electrical Systems) is designed to address the last-mentioned constraint, especially in today’s context where the field of electrical power is not perceived as being ‘cool’ unlike computers and communications and other similar nascent fields experiencing explosive growth. But it is often forgotten that even a highly complex and sophisticated data centre needs huge amounts of power of extremely high reliability, without which it is just so much silicon (and copper).

This program presents the topics at two levels. The first year addresses the design level where the student learns how to design the components of a power system such as generation, transmission and distribution as well as the other systems contributing to the safety of operation. The topics in the first year also cover the automation and control components that contribute to the high level of reliability expected from today’s power systems. Because of the constraints imposed by the fuel for power generation and the environmental degradation that accompanies power generation by fossil fuels, the attention today is focused on renewable energy sources and also more importantly how to make the generation of power more efficient and less polluting so that you get a double benefit of lower fuel usage and lower environmental impact. Even the best designed systems need to be put together efficiently. Setting up power generation and transmission facilities involves appreciable capital input and complex techniques for planning, installation and commissioning. Keeping this in view, a unit covering project management is included in the first year.

The second year of the program focuses on the highly complex theory of power systems. If the power system has to perform with a high degree of reliability and tide over various disturbances that invariably occur due to abnormal events in the power system, it is necessary to use simulation techniques that can accurately model a power system and predict its behavior under various possible disturbance conditions. These aspects are covered in the course units dealing with power system analysis and stability studies for steady-state, dynamic and transient conditions. The aspect of power quality and harmonic flow studies is also included as a separate unit.

The study of power systems has an extensive scope and besides the topics listed above, a student may also like to cover some other related topic of special interest. The ‘Special Topics in Electrical Power Systems’ unit aims to provide students with the opportunity for adding one ‘state-of-the art’ topic from a list of suggested fields. Examples are: Smart grids, Micro-grids and Geographic Information System (GIS) application in utility environment.

The Masters Thesis which spans over two complete semesters is the capstone of the program, requiring a high level of personal autonomy and accountability, and reinforces the knowledge and skill base developed in the preceding units. As a significant research component of the course, this program component will facilitate research, critical evaluation and the application of knowledge and skills with creativity and initiative, enabling the students to critique current professional practice in the electrical power industry.

WHO WOULD BENEFIT

Those seeking to achieve advanced know-how and expertise in industrial automation, including but not limited to:

- Electric Utility engineers

- Electrical Engineers and Electricians

- Maintenance Engineers and Supervisors

- Energy Management Consultants

- Automation and Process Engineers

- Design Engineers

- Project Managers

- Consulting Engineers

- Production Managers

Read less
The 1-year Electrical Power Systems Masters/MSc is good, the 2-year Electrical Power Systems with Advanced Research Masters/MSc is even better!. Read more
The 1-year Electrical Power Systems Masters/MSc is good, the 2-year Electrical Power Systems with Advanced Research Masters/MSc is even better!

The 3rd energy industry revolution is taking place where the key is the development of electrical power systems in the contexts of smart grids. Electrical power systems are playing a pivotal role in the development of a sustainable energy supply, enabling renewable energy generation. Globally there is a big shortage of skilled engineers for designing, operating, controlling and the economic analysis of future electricity networks – smart grids

The new 2-year MSc Electrical Power Systems with Advanced Research will give you the timely advanced skills and specialist experience required to significantly enhance your career in the electrical power industry. The programme builds on a very close involvement with the power industry, the education of power engineers and extensive research work and expertise as well as the successful experience on the 1-year MSc Electrical Power Systems at the University of Birmingham. The 2-year MSc Electrical Power Systems with Advanced Research will be able to fill in the gap of skills between the 1-year MSc and PhD research.

Some modules will be taught by leading industry experts, which will give you the exciting opportunity to understand the real challenges that power industry is facing, hence propose innovative solutions. In addition, students working on relevant MSc projects may have the opportunity to work with leading industry experts directly.

The new 2-Year MSc Electrical Power Systems with Advanced Research will run in parallel with the existing 1-Year MSc Electrical Power Systems. The taught credits in the 1st year of the 2 Year MSc are identical to that of the 1-Year MSc while the 2nd Year is mainly focused on a research project.

This programme also aims to provide graduates with the ability to critically evaluate methodologies, analytical procedures and advanced research methods. Year 1 of the programme is focussed on the taught modules covering:

Control concepts and methods
Advanced energy conversion systems and power electronic applications
Advanced power electronic technologies for electrical power networks – HVDC and FACTS
Electrical power system engineering - using state-of-the-art computational tools and methods, and design of sustainable electrical power systems and networks
Economic analysis of electrical power systems and electricity markets.
While Year 2 of the programme will give you the opportunity to work on an advanced research project. For some suitable projects, in conjunction with joint industry supervisions, industry placement may be available.

It is envisaged there will be the opportunity for students to transfer between the two programmes using the University’s procedures for transfers between programmes, subject to programme requirements. This opportunity would take place at the end of the taught part of the programme.

About the School of Electronic, Electrical & Systems Engineering

Electronic, Electrical and Systems Engineering, is an exceptionally broad subject. It sits between Mathematics, Physics, Computer Science, Psychology, Materials Science, Education, Biological and Medical Sciences, with interfaces to many other areas of engineering such as transportation systems, renewable energy systems and the built environment.
Our students study in modern, purpose built and up to date facilities in the Gisbert Kapp building, which houses dedicated state-of-theart teaching and research facilities. The Department has a strong commitment to interdisciplinary research and boasts an annual research fund of more than £4 million a year. This means that wherever your interest lies, you can be sure you’ll be taught by experts in the field.

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/pgfunding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/pgopendays

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

Read less
COURSE AIMS. This MSc programme meets the industrial demand for the training and education of both existing and future engineers in the advanced concepts of sustainable electrical power and energy generation. Read more
COURSE AIMS
This MSc programme meets the industrial demand for the training and education of both existing and future engineers in the advanced concepts of sustainable electrical power and energy generation. This programme aims to produce graduates of the highest calibre with the right skills and knowledge who will be capable of leading in teams involved in the operation, control, design, regulation and management of the power systems and networks of the future.

This programme also aims to provide graduates with the ability to critically evaluate methodologies, analytical procedures and research methods in:

Power system engineering – using state-of-the-art computational tools and methods;
Design of sustainable electrical power systems and networks;
Regulatory frameworks for, and operation of, power systems and electricity markets.
Who should Study this Course?
This newly designed M.Sc. programme is appropriate for those seeking an in-depth knowledge of sustainable electrictrical power including:

Graduates in power or electrical engineering, physical sciences, or related disciplines who aspire to work in the electrical power industry;
Industrially experienced graduate engineers and managers who recognise the importance of developing new analytical and critical skills, and state-of-the-art methodologies associated with the development sustainable electrical power systems.

COURSE MODULES

Sustainable Power Generation

Generation costing of solar, geo-thermal, bio-mass, wind, hydro, tidal, and wave.
Storage technologies and energy conversion: practical understanding and limitations.
Embedded renewable generation: technical challenges, opportunities and connection in electrical transmission and distribution grids.

Energy Economics and Power Markets

Principles, objectives, regulation, computational methods, economic procedures, emissions trading, and operation of electricity markets.
Restructuring and deregulation in generation, transmission, and distribution.
Concepts of transmission congestion and demand side management.

Power System Analysis and Security

Capabilities and limitations of modern power systems design.
Accurate use of power systems modelling and analysis of secure operation.
Computational techniques for power systems modelling, optimal power flow, mathematical programming, heuristic methods, artificially intelligent methods.

Power System Operation and Management

Business drivers and technical requirements for operational management.
In-depth knowledge of operational management software.
Energy balance and intermittency in sustainable electrical power system operation and management.

Power Electronics and FACTS

Practical understanding of how to design advanced power electronic circuits.
Modern power electronic integration techniques and state-of-the-art Flexible AC Transmission Systems.
Capabilities and limitations of different power electronic circuits.
Integration of power electronic circuits into Flexible AC Transmission Systems.

Power System Stability and Control

How to ensure effective power system stability and control power system operation using computational methods.
Power system stability problems, static and dynamic, relaying and protection, stability control and protection design, excitation and power system stabilisers.

Project Management

Formal methods and skills to function effectively at high levels of project management.
Development of skills to achieve practical business objectives.

Sustainable Electrical Power Workshop
You will gain experience and expertise with industry relevant tools and techniques through hands-on workshop environments. These practical sessions involve individual and group work. Typical assignments include:

Sustainable generation scheduling.
Integration of renewable energy sources.
Computer simulation of active power filters.
Phase-controlled rectifiers.
Power network security.
Sustainable electrical power system stability control.
Electricity market auctions.
Sustainable electrical power system investment and planning.

Project
This provides a stimulating and challenging opportunity to apply your knowledge and develop deep understanding in a specialised aspect of your choice. Projects can be university or industry and company sponsored students have the opportunity to develop their company’s future enterprise. Industrial projects often lead to the recruitment of the student by the collaborating company.

Read less
This course has been designed to meet the industrial demand for the training and education of both existing and future engineers in the advanced concepts of sustainable electrical power and energy generation. Read more
This course has been designed to meet the industrial demand for the training and education of both existing and future engineers in the advanced concepts of sustainable electrical power and energy generation.

Who is it for?

This course is suitable for both practicing engineers and those considering a career in engineering.

The course has been designed to provide an in-depth insight into the technical workings, management and economics of the electrical power industry.

Objectives

This programme has been designed to meet the industrial demand for the training and education of both existing and future engineers in the advanced concepts of sustainable electrical power and energy generation. The aims are to produce graduates of a high calibre with the right skills and knowledge who will be capable of leading teams involved in the operation, control, design, regulation and management of power systems and networks of the future.

The programme aims to:
-Provide you with the ability to critically evaluate methodologies, analytical procedures and research methods.
-Provide an advanced education in electrical power engineering.
-Give you the education, knowledge and the skills you need to make sound decisions in a rapidly changing electricity supply industry.
-Provide a sound understanding of the principles and techniques of electrical power engineering.
-Give a broad knowledge of the issues and problems faced by electrical power engineers.
-Give a solid working knowledge of the techniques used to solve these problems.
-Provide a foundation in power systems principles for graduates with an engineering background.
-Demonstrate the practical relevance of these principles to the operation of successful enterprises in the broad field of electrical power engineering.
-Familiarise professional engineers and graduates with the theory and application of new technologies applied to power systems.

Academic facilities

Students in City's Department of Electronic and Electrical Engineering benefit from a recent lab equipment upgrade worth £130,000. This includes photovoltaic trainers, three phase synchronous machines, AC motor speed control machines, single and three phase transformers, thryistor controllers, a power systems mainframe and power systems virtual instrumentation.

The equipment is essential in training students to be highly skilled professionals in the energy industry.

The photovoltaic trainer, for instance, is a desk-top instrument which teaches the fundamental principles of photovoltaic energy. The 'photovoltaic effect' is a method of energy generation which converts solar radiation into an electrical current using semiconductors arranged into solar cells.

Teaching and learning

Modules are delivered by academics actively involved in energy related research, as well as visiting lecturers from the power industry who provide a valuable insight into the operation of energy companies.

Industry professionals give several seminars throughout the year. At least two industrial trips are organised per academic year.

Modules

The modules for this course are delivered over two semesters, with weekly lessons scheduled over two days a week. The third semester is spent completing a project that involves writing a dissertation and presenting findings. This course is organised into eight modules provided on a weekly basis.

Course content
-Introduction to Power Systems & Energy Management EPM874 (15 credits)
-Systems Modelling EPM744 (15 credits)
-Renewable Energy Fundamentals and Sustainable Energy Technologies EPM879 (15 credits)
-Transmission and Distribution Systems Management EPM875 (15 credits)
-Power Systems Design and Simulation EPM423 (15 credits)
-Power Electronics EPM501 (15 credits)
-Power Systems Protection and Grid Stability EPM990 (15 credits)
-Economics of the Power Industry EPM101 (15 credits)
-Dissertation EPM949 (60 credits)

Career prospects

Graduates are prepared for careers that encompass a variety of roles in the power industry, from technical aspects to management roles. Previously graduates have found jobs as engineers, managers and analysts in the power sector, with companies such as:
-OFGEM
-National Grid
-UK Power Networks
-EON
-EDF
-Vattenfall
-Caterpillar
-Railroad
-Graduates may also wish to further their research in the energy field by considering a PhD

Read less
IN THIS INTENSIVE, PART-TIME, 18-MONTH ONLINE PROGRAM YOU WILL GAIN. - Skills and know-how in the latest technologies in electrical engineering. Read more
IN THIS INTENSIVE, PART-TIME, 18-MONTH ONLINE PROGRAM YOU WILL GAIN:

- Skills and know-how in the latest technologies in electrical engineering
- Practical guidance from electrical engineering experts in the field
- Knowledge from the extensive experience of the lecturers, rather than from only the theoretical information gained from books and college
- Credibility as the local electrical engineering expert in your firm
- Networking contacts in the industry
- Improved career prospects and income
- An Advanced Diploma of Applied Electrical Engineering (Electrical Systems)

Next intake starts October 09, 2017. Registrations are now open.

Payment is not required until 2 to 4 weeks before the start of the program.

The EIT Advanced Diploma of Applied Electrical Engineering (Electrical Systems) is recognized worldwide and has been endorsed by the International Society of Automation (ISA). Please ask us about specific information on accreditation for your location.

OVERVIEW

Join the next generation of electrical engineers and technicians and embrace a well paid, intensive yet enjoyable career by embarking on this comprehensive course on electrical engineering. It is presented in a practical and useful manner - all theory covered is tied to a practical outcome. Leading electrical engineers who are highly experienced engineers from industry, having 'worked in the trenches' in the various electrical engineering areas present the course over the web in a distance learning format using our acclaimed live e-learning techniques.

The course starts with an overview of the basic principles of electrical engineering and then goes on to discuss the essential topics in depth. With a total of 16 modules, everything that is of practical value from electrical distribution concepts to the equipment used, safety at work to power quality are all looked at in detail. Each module contains practical content so that the students can practice what they learn including the basic elements of designing a system and troubleshooting.

Most academic courses deal with engineering theory in detail but fall short when it comes to giving practical hints on what a technician is expected to know for a job in the field. In this course, the practical aspects receive emphasis so that when you go out into the field you will have the feeling that ‘you have seen it all.

*JOB OUTCOMES, INTERNATIONAL RECOGNITION AND PROFESSIONAL MEMBERSHIP:

A range of global opportunities awaits graduates of the Advanced Diploma of Applied Electrical Engineering (Electrical Systems). Pending full accreditation you may become a full member of Engineers Australia and your qualification will be recognized by Engineers Australia and (through the Dublin Accord) by leading professional associations and societies in Australia, Canada, Ireland, Korea, New Zealand, South Africa, United Kingdom and the United States. The Dublin Accord is an agreement for the international recognition of Engineering Technician qualifications.

For example, current enrolled students can apply for free student membership of Engineers Australia. After graduation, you can apply for membership to become an Engineering Associate, while graduates interested in UK recognition can apply for membership of the Institution of Engineering and Technology (IET) as a Technician Member of the Institution of Engineering and Technology.

This professional recognition greatly improves the global mobility of graduates, and offers you the opportunity of a truly international career.

You will be qualified to find employment as an Engineering Associate in public and private industry including transportation, manufacturing, process, construction, resource, energy and utilities industries. Engineering Associates often work in support of professional engineers or engineering technologists in a team environment. If you prefer to work in the field you may choose to find employment as a site supervisor, senior technician, engineering assistant, or similar.

WHO SHOULD COMPLETE THIS PROGRAM?

- Electrical Engineers and Technicians
- Project Engineers
- Design Engineers
- Instrumentation and Design Engineers
- Electrical Technicians
- Field Technicians
- Electricians
- Plant Operators
- Maintenance Engineers and Supervisors
- Energy Management Consultants
- Automation and Process Engineers
- Design Engineers
- Project Managers
- Instrument Fitters and Instrumentation Engineers
- Consulting Engineers
- Production Managers
- Chemical and Mechanical Engineers
- Instrument and Process Control Technicians

In fact, anyone who wants to gain solid knowledge of the key elements of electrical engineering – to improve work skills and to create further job prospects. Even those of you who are highly experienced in electrical engineering may find it useful to attend some of the topics to gain key, up to date perspectives on electrical engineering.

PROGRAM STRUCTURE

The course is composed of 16 modules. These cover the following seven main threads to provide you with maximum practical coverage in the field of electrical engineering

- Electrical technology fundamentals
- Distribution equipment and protection
- Rotating machinery and transformers
- Power electronics
- Energy efficiency
- Earthing and safety regulations
- Operation and maintenance of electrical equipment

The 16 modules will be completed in the following order:

- Electrical Circuits
- Basic Electrical Engineering
- Fundamentals of Professional Engineering
- Electrical Drawings
- Electrical Power Distribution
- Transformers, Circuit Breakers and Switchgear
- Electrical Machines
- Power Cables and Accessories
- Earthing and Lightning / Surge Protection
- Power System Protection
- Electrical Safety and Wiring Regulations
- Testing, Troubleshooting and Maintenance of Electrical Equipment
- Energy Efficiency and Energy Use
- Power Quality
- Power Electronics and Variable Speed Drives
- DC and AC High Reliability Power Supplies

COURSE FEES

What are the fees for my country?

The Engineering Institute of Technology (EIT) provides distance education to students located all around the world – it is one of the very few truly global training institutes. Course fees are paid in a currency that is determined by the student’s location. We aim to give you a rapid response regarding course fees that are relevant to your individual circumstances.

We understand that cost is a major consideration before a student begins to study. For a rapid reply to your query regarding course fees and payment options, please contact a Course Advisor in your region via the below button and we will respond within two (2) business days.

Read less
Take advantage of one of our 100 Master’s Scholarships to study Electronic and Electrical Engineering at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Electronic and Electrical Engineering at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

As a student on the Master's course in Electronic and Electrical Engineering, you will develop specialist skills aligned with the College of Engineering’s research interests and reflecting the needs of the electronics industry.

Key Features of MSc in Electronic and Electrical Engineering

The MSc Electronic and Electrical Engineering course covers the ability to apply the knowledge gained in the course creatively and effectively for the benefit of the profession, to plan and execute a programme of work efficiently, and to be able, on your own initiative, to enhance your skills and knowledge as required throughout your career in Electronic and Electrical Engineering.

Students on the Electronic and Electrical Engineering course benefit from the use of industry-standard equipment, such as a scanning tunnelling microscope for atomic scale probing or an hp4124 parameter analyzer for power devices, for simulation, implementation and communication.

During the Electronic and Electrical Engineering course there will be the opportunity to choose and apply suitable prototyping and production methods and components, gain knowledge in constructing and evaluating advanced models of various manufacturing techniques, and be able to differentiate, analyse and discuss various product lifetime management solutions and how they affect different sectors of Electronic and Electrical Engineering industry.

The MSc in Electronic and Electrical Engineering programme 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 in Electronic and Electrical Engineering. Students on the Electronic and Electrical Engineering course must successfully complete Part One before being allowed to progress to Part Two.

Part-time Delivery mode of MSc in Electronic and Electrical Engineering

The part-time scheme of the MSc in Electronic and Electrical Engineering is a version of the full-time equivalent MSc in Electronic and Electrical Engineering 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 in Electronic and Electrical Engineering.

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 Electronic and Electrical Engineering

Modules on the MSc Electronic and Electrical Engineering course can vary each year but you could expect to study:

Communication Skills for Research Engineers
Energy and Power Electronics Laboratory
Power Semiconductor Devices
Advanced Power Electronics and Drives
Wide Band-Gap Electronics
Power Generation Systems
Modern Control Systems
Advanced Power Systems
Signals and Systems
Digital Communications
Optical Communications
Probing at the Nanoscale
RF and Microwaves
Wireless Communications

Facilities for Electronic and Electrical Engineering

The new home of the Electronic and Electrical Engineering programme is at the innovative Bay Campus which 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.

Find out more about the facilities used by Electronic and Electrical students at Swansea University, including the electronics lab on our website.

Links with Industry

At Swansea University, Electronic and Electrical Engineering has an active interface with industry and many of our activities are sponsored by companies such as Agilent, Auto Glass, BT and Siemens.

Electronic and Electrical Engineering has a good track record of working with industry both at research level and in linking industry-related work to our postgraduate courses. We also have an industrial advisory board that ensures our taught courses including the MSc in Electronic and Electrical Engineering maintain relevance.

Our research groups work with many major UK, Japanese, European and American multinational companies and numerous small and medium sized enterprises (SMEs) to pioneer research. This activity filters down and influences the project work that is undertaken by all our postgraduate students including those on the MSc in Electronic and Electrical Engineering.

Careers

Electronic and Electrical Engineering graduates find employment in industry, research centres, government or as entrepreneurs in a wide range of careers, from a design and development role for electronic and electrical equipment or as a technological specialist contributing to a multi-disciplinary team in a range of fields, including medicine, travel, business and education.

Research

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.

World-Leading Research

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.

Read less
Energy Engineering is the branch of engineering concerned with the design and the management of energy plants and their components in order to ensure the best use of the available resources with the minimum environmental impact. Read more

Mission and goals

Energy Engineering is the branch of engineering concerned with the design and the management of energy plants and their components in order to ensure the best use of the available resources with the minimum environmental impact. Energy plants are systems in which energy forms are transformed and utilized. To name a few examples: large thermal power stations, air-conditioning and climate control equipment for residences and offices, vehicle engines, airplane propellers, solar panels etc.
The Master of Science in Energy Engineering prepares professionals to design, select and use the main technologies in energy transformation, to actively follow scientific improvements and to operate effectively in a competitive and multi-disciplinary industrial context, characterized by significant environmental, regulatory and safety constraints. Students will analyze broad themes as well as specific subjects for which both a rigorous methodological approach to thermodynamics and an open attitude towards related interdisciplinary topics are required.

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/energy-engineering/energy-engineering-track/

Professional opportunities

Graduates can find employment in several sectors: in the technical area of designing, testing, running, and maintaining the energy systems, like heating and cooling systems, thermal power and hydro-electric power plants, engines, oil and gas fields; in the energy management area; and in utilities and public boards that supply energy as electricity and natural gas.

Presentation

See http://www.polinternational.polimi.it/uploads/media/Energy_Engineering_MI.pdf
Energy Engineering is the branch of engineering concerned with the design and the management of energy plants and their components in order to ensure the best use of the available resources with the minimum environmental impact. Energy plants are
systems in which energy forms are transformed and utilized. To name a few examples: large thermal power stations, air-conditioning and climate control equipment for residences and offices, vehicle engines, airplane propellers, solar panels etc. The Master of Science in Energy Engineering prepares professionals to design, select and use the main technologies in energy transformation, to actively follow scientific improvements and to operate effectively in a competitive and multi-disciplinary industrial context, characterized by significant environmental, regulatory and safety constraints. Students will analyze broad themes as well as specific subjects for which both a rigorous methodological approach to thermodynamics and an open attitude towards related interdisciplinary topics are required.
Graduates can find employment in several sectors: in the technical area of designing, testing, running, and maintaining the energy systems, like heating and cooling systems, thermal power and hydro-electric power plants, engines, oil and gas fields; in the energy management area; and in utilities and public boards that supply energy as electricity and natural gas. The programme is taught in English.

Subjects

- Five tracks available: Power Production; Heating, Ventilation and Air-Conditioning; Oil and Gas Engineering; Energy Engineering for an Environmentally Sustainable World (offered on Piacenza campus, see separate leaflet); Energy for Development.

- Subjects and courses common to all the tracks: Heat and Mass Transfer; Fundamentals of Chemical Processes; Advanced Energy Engineering and Thermoeconomics;; Combustion and Safety; Energy Conversion or Refrigeration, Heat Pumps and Thermal Power Systems and Components; Energy Economics or Project Management or Management Control Systems; Graduation Thesis.

- Optional subjects according to the selected track: Development Economy; Engineering and Cooperation for Development; Power Production from Renewable Sources; Engineering of Solar Thermal Processes; Petroleum Reservoir Engineering; Petroleum Technology and Biofuel; Transport Phenomena in the Reservoirs; CFD for Energy Engineering Analysis; System and Electrical Machines; Advanced Energy Systems; Dynamic Behavior and Diagnostics of Machines; Materials for Energy; Turbomachinery; Internal Combustion Engines; Air Conditioning and Room Pollutant-Controlling Plants, Energy Savings and Renewable Energies in Buildings; Applied Acoustics and Lighting; Design of Thermal Systems; Energy Systems and Low-Carbon Technologies; Air Pollutions and Control Engineering; Operation and Control of Machines for Power Generation; Bio-energy and Waste-to-Energy Technologies; Smart Grids and Regulation for Renewable Energy Sources.

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/energy-engineering/energy-engineering-track/

For contact information see here http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/energy-engineering/energy-engineering-track/

Find out how to apply here http://www.polinternational.polimi.it/how-to-apply/

Read less
Effective use of renewable energy and improvements in the efficiency of power generation facilities will enable better energy management in the future and help reduce environmental impact. Read more

Why take this course?

Effective use of renewable energy and improvements in the efficiency of power generation facilities will enable better energy management in the future and help reduce environmental impact. This course responds to an urgent need for specialists in energy and power systems management, as well as a growing skills shortage of people with core knowledge in this field.

The course provides relevant, up-to-date skills that will equip both graduates and working professionals in the advanced concepts of sustainable electrical power and energy generation. It offers skills for operation, control, design, regulation and management of power systems and networks of the future. You will also receive training in and understanding of energy production, delivery, consumption and efficiency.

What will I experience?

On this course you will:

Benefit from experts in the industry who will deliver part of the course as visiting lecturers, bringing professional expertise and industry-relevant material
Be encouraged to reach a level of competence and professionalism where you can effectively integrate your technical and non-technical knowledge to solve a range of problems of a complex nature
Learn in a challenging and stimulating study environment
Develop a range of key skills by means of opportunities provided in the study units
Being an MSc course, you are encouraged and expected to be able to reach a level of competence and professionalism where you can effectively integrate your technical and non-technical knowledge to solve a range of problems of a complex nature.

What opportunities might it lead to?

The course will help to maximise your career potential in this field and equips you to work as an engineer, at an advanced level, in the fields of energy and power systems management.

Module Details

You will study several key topics and complete a four-month individual project in which you apply your knowledge to a significant, in-depth piece of analysis or design. Projects are tailored to your individual interests and may take place in our own laboratories or, by agreement, in industry. Experts from Industry (STS Nuclear) deliver part of the course as visiting lecturers, bringing professional expertise and industry-relevant material to the programme.

Here are the units you will study:

Power Systems Technology: This unit provides an in-depth overview of contemporary electrical power systems. It covers the elements of electrical power systems including generation, transmission and distribution in the mixed energy source paradigm.

Electrical Machines and drives: Provides an in-depth overview of the operational principles and physical design of DC and AC electrical machines as well as broad understanding of concepts of power electronics and power electronic converters, so that you can describe their application and selection criteria. You will develop an understanding of the issues present in converter design, including the impact of physical layout and heat dissipation.

Energy Systems: Focuses on the techniques and principles of operation of thermodynamics and combustion systems, as well as the provision and management of energy. It also focuses on power generation and combined systems, BioMass processers application of heat and fluid transfer.

Renewable and Alternative Energy: Provides an in-depth coverage of the principles of renewable and alternative energy systems: Winds, Solar, BioMass, Geothermal, Fuel Cells, Hydrogen Technologies and Nuclear Energy.

Nuclear Technology: A study of nuclear engineering including the theory of atomic and nuclear physics, methods and benefits of generating electricity from nuclear power plants, and the effects of ionising radiation. The nuclear fuel cycle and the associated environmental impacts are also considered. The development of international guidance on nuclear and radiological safety and a comparison of national regulatory structures are analysed. The importance of safety cultures, safety behaviours and safety cases is a key element throughout this module.

Energy Management: The unit is specifically designed to provide the students with the basic of economical analysis and evaluation of energy projects and asset management as well as risk and hazard assessment, comprising legislation, hazard identification and quantification, quantified risk analyses, methods of elimination/mitigation, economic appraisal of integrated renewable, and petroleum projects; with numerous pertinent case studies.

Programme Assessment

You will be taught through a mixture of lectures, seminars, tutorials (personal and academic), laboratory sessions and project work. The course has a strong practical emphasis and you will spend a significant amount of time in our Energy, Power systems and Electronic laboratories.

A range of assessment methods encourages a deeper understanding of engineering and allows you to develop your skills. Here’s how we assess your work:

Written examinations
Coursework
Laboratory-based project work
A major individual project/dissertation

Student Destinations

This course is designed to respond to a growing skills shortage of people with core knowledge in energy and power systems management. It is an excellent preparation for a successful career in this ever expanding and dynamic field.

On successful completion of the course, you will have gained the skills and knowledge that will make you attractive to a wide variety of employers with interests ranging from overall system design to the more detailed development of subsystems. You will acquire the ability to critically evaluate methodologies, analytical procedures and research methods in energy and power systems management and in the use of state-of-the-art computational tools, the design of sustainable electrical power systems and networks and regulatory frameworks. For practicing engineers with professional business experience, the course is an opportunity to update your knowledge of current design practice and also to familiarise themselves with developments in codes and methods of analysis.

Read less
Do you want to be able to help design the next generation of renewable energy systems, clean cars and aircraft? Do you want to be able to invent the electrical systems for future factories and robots?. Read more
Do you want to be able to help design the next generation of renewable energy systems, clean cars and aircraft? Do you want to be able to invent the electrical systems for future factories and robots?

The Power Electronics, Machines and Drives (PEMD) is a 1 year degree course that provides its students with the knowledge to design, construct and analyse integrated networks of power electronic converters, electrical machines, actuators, energy storage devices, and control systems. As a result of recent technical advances, PEMD technology is becoming commonplace and can be found for example in more-electric aircraft and ships, electric vehicles, railway systems, renewable power generation, active management of power distribution systems, automation systems for factories and industrial processes. The adoption of PEMD technology is being driven by the need to increase energy efficiency, and controllability, whilst reducing system weight and maintenance costs.

This MSc course has been designed to equip electrical engineers with the knowledge and skills that are required to design modern PEMD systems, it includes the fundamentals of electrical machine and power electronics design, system integration, control, energy management and protection. The teaching team of eight academic staff belong to the Power Conversion Group and are all actively involved in researching new aspects of machines, drives, power electronics and electrical systems, particularly for applications in transport and sustainable electricity supply. The Group's research activities and industrial links inform the course content and enrich the student experience.

Aims

-To enable you to gain experience in the design and analysis of systems in electrical engineering, for example renewable energy, more-electric aircraft, vehicles, and next-generation electric power transmission
-To enable you to critically evaluate electrical machine and converter technology applied in manufacturing, power systems and transport industries
-To employ recent developments in these research areas and to prepare students who wish to continue on to research studies
-To develop your ability to integrate strands of machines, power electronics, drives and their control

The MSc course begins with an introduction to the fundamentals of converters, machines, actuators and relevant control systems. The course will give you a high level of exposure to system integration and is illustrated by a broad range of high-technology activities related to industrial and other systems.

The next five course units give specialist tuition on advanced topics including machine design, systems analysis, converter circuits and applications. In addition to lectures, tutorials, design exercises and enquiry-based learning, you will attend industrial seminars and practical laboratories which employ mainly industrial equipment. The course will include a `mechatronic' emphasis in examining how system blocks interact and ensuring that electrical and mechanical systems work together.

The summer is spent on this individual dissertation project, which is strongly supported by the Power Conversion Research Group's research base (including the Rolls-Royce University Technology Centre) and extensive industrial contacts. Cutting-edge research areas include versatile power and conversion systems for a variety of applications, including more-electric aircraft and ships, electric and hybrid vehicles, automation systems and autonomous/micro-grid power systems.

Career opportunities

Graduates of the course will have acquired in-depth education in modern design, broad exposure to the expanding range of applications, hands-on experience and integration into state-of-the-art systems. These comprise the special knowledge and skills needed for a professional career in energy conversion systems, an area in which engineers are in demand for key power electronic/drives/automation industries.

Industry's competitive edge relies on high-technology drives and in the integration of systems to provide superior overall performance. Applications include the `more electric aircraft', electric transport and high-reliability systems.

Our students have been employed by companies such as:
-ABB
-BAE Systems
-Cummings Turbo Technologies
-GE Energy
-National Instruments
-Rolls-Royce
-Siemens

Opportunities also exist for further study to doctoral level (PhD) in the Power Conversion Group's recently re-equipped and expanding research laboratories.

Read less

Show 10 15 30 per page


Share this page:

Cookie Policy    X