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Masters Degrees (Power And Energy)

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This programme is for graduate engineers wishing to work in the electrical power industry. It develops your knowledge of electrical power and energy systems, giving you a good understanding of the latest developments and techniques within the electrical power industry. Read more

This programme is for graduate engineers wishing to work in the electrical power industry. It develops your knowledge of electrical power and energy systems, giving you a good understanding of the latest developments and techniques within the electrical power industry.

Course details

The programme is centred around three major themes:

  • electrical power networks with emphasis on conventional networks, smart grids, high voltage direct current transmission and asset management of network infrastructure
  • renewable energies with emphasis on wind and solar power
  • power electronics with emphasis on power electronic convertors in converting and controlling power flows in electrical networks and renewable energy systems.

There are three routes you can select from to gain a postgraduate Master’s award:

  • MSc Electrical Power and Energy Systems – one year full time
  • MSc Electrical Power and Energy Systems – two years part time
  • MSc Electrical Power and Energy Systems (with Advanced Practice) – two years full time

The one-year programme is a great option if you want to gain a traditional MSc qualification – you can find out more here. This two-year master’s degree with advanced practice enhances your qualification by adding to the one-year master’s programme an internship, research or study abroad experience.The MSc Electrical Power and Energy Systems (with Advanced Practice) offers you the chance to enhance your qualification by completing an internship, research or study abroad experience in addition to the content of the one-year MSc.

What you study

For the MSc with advanced practice, you complete 120 credits of taught modules, a 60-credit master’s research project and 60 credits of advanced practice.

Course structure

Core modules

  • Asset Management
  • Data Acquisition and Signal Processing Techniques
  • Emerging Transmission Systems
  • Power Electronics
  • Practical Health and Safety Skills
  • Project Management and Enterprise
  • Renewable Energy Conversion Systems
  • Research and Study Skills
  • Research Project (Advanced Practice)
  • Smart Power Distribution

Advanced Practice options

  • Research Internship
  • Study Abroad
  • Vocational Internship

Modules offered may vary.

Teaching

How you learn

You learn through lectures, tutorials and practical sessions. Lectures provide the theoretical underpinning while practical sessions give you the opportunity to put theory into practice, applying your knowledge to specific problems. 

Tutorials and seminars provide a context for interactive learning and allow you to explore relevant topics in depth. In addition to the taught sessions, you undertake a substantive MSc research project.

In addition to the taught sessions, you undertake a substantive MSc research project and the Advanced Practice module. This module enables you to experience and develop employability or research attributes and experiential learning opportunities in either an external workplace, internal research environment or by studying abroad. You also critically engage with either external stakeholders or internal academic staff, and reflect on your own personal development through your Advanced Practice experience.

How you are assessed

Assessment varies from module to module. It may include in-course assignments, design exercises, technical reports, presentations or formal examinations. For your MSc project you prepare a dissertation.

Your Advanced Practice module is assessed by an individual written reflective report (3,000 words) together with a study or workplace log, where appropriate, and through a poster presentation.

Employability

As an electrical power and energy systems engineer you can be involved in designing, constructing, commissioning and lifecycle maintenance of complex energy production, conversion and distribution systems. 

Your work can include energy storage systems, management and efficient use of energy in building, manufacturing and processing systems. You can also be involved in work relating to the environmental and economic impact of energy usage.

Examples of the types of jobs you could be doing include:

  • designing new electrical transmission and distribution systems
  • managing maintenance and repair
  • managing operations of existing systems
  • managing operations of a wind turbine farm
  • analysing the efficiency of hydroelectric power systems
  • evaluating the economic viability of new solar power installations
  • assessing the environmental impact of energy systems.


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The MRes Electrical Power and Energy Technology programme provides advanced and systematic education and training in the areas of electronic science and technology. Read more

The MRes Electrical Power and Energy Technology programme provides advanced and systematic education and training in the areas of electronic science and technology. It has been designed to respond to the vigorous development of electric power and energy technology in China and worldwide.

The programme contains taught courses covering solar converters, wind power systems, energy storage technology, and smart grids. It places strong emphasis on hands-on experience and practical skills development. A 12-month extensive research project is required which leads to submission of a dissertation after students have finished the taught modules.

You will develop the understanding of state-of-the-art electrical power and energy technology; be able to research and critically evaluate trends in current technologies of energy management, sustainability, renewable energy and nuclear energy; skills in planning, project management and communicating complex ideas; and experience in conducting extended research and/or developing project work.

You will benefit from:

  • excellent research platform equipped with advanced experimental equipment, including network analyser, power analyser and electrical machine testing system etc.
  • cutting-edge research areas that aim for the intelligent and efficient utilisation of emerging electrical power and energy technologies
  • close cooperation with world famous universities and research centres to solve major challenges.
  • additional learning activities provided to improve students’ research and design skills, such as module CEN901 Research Methods (Information Management and Expression).


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This programme is for graduate engineers wishing to work in the electrical power industry. It develops your knowledge of electrical power and energy ystems, giving you a good understanding of the latest developments and techniques within the electrical power industry. Read more

This programme is for graduate engineers wishing to work in the electrical power industry. It develops your knowledge of electrical power and energy ystems, giving you a good understanding of the latest developments and techniques within the electrical power industry.

Course details

The programme is centred around three major themes:

  • electrical power networks with emphasis on conventional networks, smart grids, high voltage direct current transmission and asset management of network infrastructure
  • renewable energies with emphasis on wind and solar power
  • power electronics with emphasis on power electronic convertors in converting and controlling power flows in electrical networks and renewable energy systems.

What you study

For the postgraduate diploma (PgDip) award you must successfully complete 120 credits of taught modules. 

For MSc students

For an MSc award you must successfully complete 120 credits of taught modules and a 60-credit master's research project.

Course structure

Core modules

  • Asset Management
  • Emerging Transmission Systems
  • Power Electronics
  • Practical Health and Safety Skills
  • Project Management and Enterprise
  • Renewable Energy Conversion Systems
  • Research and Study Skills
  • Smart Power Distribution

MSc only

  • Major Project

Modules offered may vary.

Teaching

How you learn

You learn through lectures, tutorials and practical sessions. Lectures provide the theoretical underpinning while practical sessions give you the opportunity to put theory into practice, applying your knowledge to specific problems. 

Tutorials and seminars provide a context for interactive learning and allow you to explore relevant topics in depth. In addition to the taught sessions, you undertake a substantive MSc research project.

How you are assessed

Assessment varies from module to module. The assessment methodology could include in-course assignments, design exercises, technical reports, presentations or formal examinations. For your MSc project you prepare a dissertation.

Employability

As an electrical power and energy systems engineer you can be involved in designing, constructing, commissioning and lifecycle maintenance of complex energy production, conversion and distribution systems. 

Your work could include energy storage systems, management and efficient use of energy in building, manufacturing and processing systems.

You could also be involved in work relating to the environmental and economic impact of energy usage.

Examples of the types of jobs you could be doing include:

  • designing new electrical transmission and distribution systems
  • managing maintenance and repair
  • managing operations of existing systems
  • managing operations of a wind turbine farm
  • analysing the efficiency of hydroelectric power systems
  • evaluating the economic viability of new solar power installations
  • assessing the environmental impact of energy systems.


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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). Read more

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.

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.



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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/

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The Energy Policy Option aims to produce graduates capable of combining the technical, environmental, economic, and legal and policy aspects of energy use and supply in tackling energy-related problems. Read more

The Energy Policy Option aims to produce graduates capable of combining the technical, environmental, economic, and legal and policy aspects of energy use and supply in tackling energy-related problems. Students from a wide range of backgrounds are given a broad understanding of the role of energy in the global and local economy, and the range of human and environmental impacts associated with energy systems.  

The course aims to foster a range of skills, incorporating an in depth appreciation of technical subjects and quantitative methods with a balanced approach to policy analysis and communication. The ability to produce clear, critical and authoritative analysis of technical, economic and policy issues is the key aim, making graduates sought-after energy analysts, consultants and campaigners in the private and public sectors.

Aims and Objectives

Energy plays a key role in most of the world’s environmental problems, from the global issue of climate change, through regional damage caused by acid rain, to poor local air quality. Energy markets throughout the world are evolving rapidly, with privatisation, competition, market structure and regulation all prominent issues in the UK, Europe and overseas. Resource depletion of fossil fuels, the role of renewable energy and social inequities such as fuel poverty are central issues for sustainable development. The influence of energy issues on international politics and security has come into sharp focus with conflicts affecting the Middle East and the former Soviet Union. The range of challenges for energy policy is diverse and exciting.

Option Aims 

  • To build on the foundations of the core course, by developing specialist knowledge of the energy field within a more general environmental framework
  • To inform and guide the choice of project for the third term
  • To provide students from natural science, engineering, social science and other backgrounds with a broad understanding of the role of energy in the global and local economy, and of the range of economic, human and environmental impacts associated with energy systems.
  • To develop a broad range of skills, incorporating an in depth appreciation of technical subjects and quantitative methods with a balanced approach to policy analysis and communication.
  • To produce graduates capable of combining the technical, economic and policy aspects of energy, so that they can draw conclusions of strategic significance in energy areas relating to corporate, government or non-government activity.

Option Objectives

At the conclusion of the course, students should be:

  • capable of developing policy analyses and recommendations in a broad range of areas across the energy sector
  • able to understand the legislative and regulatory frameworks which surround energy markets
  • able to apply their knowledge appropriately to energy issues in both developed and developing countries
  • able to conduct cost-benefit analyses of energy projects at different scales, and from different perspectives
  • capable of constructing simple energy models, and able to appreciate the possibilities and limitations of the modelling process
  • able to write clear, critical and authoritative reports, both on technical subjects and on policy issues
  • able confidently to present results orally, at a level appropriate to their audience

Option Content

The option is broadly divided into a series of modules: Policy, Assessment & Law; Energy Economics & Markets; Energy Use; Fossil Fuels & Nuclear Power; Renewable Energy; Energy & Development; Transport Energy; Energy Modelling. Some emphasis is placed on the future role of 'clean' and/or low carbon options, such as energy efficiency and renewable energy, but the intention is to equip graduates with a working knowledge of the full extent of the energy sector.

Teaching takes place through a mixture of lectures and seminars, workshops covering professional skills, analytical techniques and modelling methods, and small group project work. Short visits are made to a number of key energy facilities, and a week long fieldtrip is used to visit a wide range of renewable energy facilities. The group projects also foster team working, report writing and oral presentation skills, which are essential for many jobs.

The Option is taught by a wide range of specialists from both within and outside Imperial College: the current year has inputs from 29 people, including 14 external experts. External contributors include well-known figures from government, industry, specialist consultancies and NGOs (for example, British Petroleum, Price Waterhouse Coopers, Intermediate Technology Development Group).

The Option is associated with a highly successful research centre within the Department. The Imperial College Centre for Energy Policy and Technology (ICEPT), brings together energy related research and expertise from the full range of the College's science and technology departments with staff working in technology assessment, economics and policy. The Centre has strong links with industry, and is emerging as the key policy research and advisory group in the clean and low carbon energy field. The Centre's activities have tremendous spin-off benefits for the Option.

Track Record and Careers

The Energy Policy Option has been running for more than 20 years. Graduates can therefore be found throughout all levels of industry, government, international agencies, consultancy and NGOs. In specialist energy/environment consultancies it is not uncommon to find that a majority of the staff are Option graduates, ranging from the Director to the new junior consultant. The network of graduates is fostered through regular reunion dinners, and is used to great success in helping current students in their thesis projects and in finding employment - of benefit to both students and employers alike.

Thesis Collaborators

Recent examples of thesis collaborators include:

  • BP
  • Shell Renewables
  • Rolls Royce
  • Nokia
  • the Energy Saving Trust
  • Energy for Sustainable Development
  • Tata Energy Research Institute, India
  • Students have travelled in recent years on thesis fieldwork to Rodrigues (near Mauritius), Sri Lanka, Zambia, Nepal, Jordan, Colombia, the Ukraine and many countries within Europe.


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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. Read more

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):

  • Fundamental and emerging power engineering technologies
  • Advanced numerical methods in application to electrical power engineering problems
  • Modern power conversion components & systems
  • Integration of renewable energy in the power system
  • Distributed energy resources
  • Electrical engineering aspects of energy storage
  • Power, telecommunications & control aspects of smart grids
  • Research and innovation management techniques.

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.

Programme structure

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.

Semester 1

  • Power Electronics, Machines & Systems
  • Power Engineering Research Techniques
  • Energy & Environmental Economics
  • Technologies for Sustainable Energy

Semester 2

  • Power Conversion and Control
  • Power Systems Engineering & Economics
  • Distributed Energy Resources and Smart Grids

Research Project

  • Electrical Power Engineering Dissertation

The above courses correspond to 120 credits of taught material, plus 60 credits of a research project.

Learning outcomes

The main objective of the programme is to train the next generation of electrical power engineers who:

  • are aware of the most recent, cutting edge developments in power engineering;
  • have skills and training needed in both industrial and academic settings;
  • are able to tackle the global energy trilemma of supplying secure, equitable and environmentally sustainable energy, while appreciating the technical, social and economic challenges faced in both developed and developing countries.

Career opportunities

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).



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Overview. This is a 12 month full-time Masters degree (See http://www.postgraduate.hw.ac.uk/prog/msc-renewable-energy-development-red-/ ) course taught at our Orkney Campus. Read more

Overview

This is a 12 month full-time Masters degree (See http://www.postgraduate.hw.ac.uk/prog/msc-renewable-energy-development-red-/ ) course taught at our Orkney Campus. It involves studying 8 taught courses and completing a research dissertation equivalent to 4 taught courses. If you can demonstrate that you have already mastered the subject, you may apply for an exemption from one of the taught courses and undertake a Design Project instead.

For more information visit http://www.hw.ac.uk/schools/life-sciences/research/icit.htm

Distance learning

The Renewable Energy Development MSc/Diploma is also available for independent distance learning. For distance learners, the main difference is that you will undertake the Development Project alone rather than as part of a group. You can still obtain the full MSc in Renewable Energy Development, or you can opt to study fewer courses, depending on your needs.

Programme content

- Energy in the 21st Century

This course is designed to give you a broad understanding of the environmental, political and socio-economic context for current developments in renewable energy. The course examines the extent of current energy resources and how energy markets function. It covers some energy basics you will need for the rest of the programme (e.g. thermodynamics, efficiency conversions) as well as environmental issues associated with energy use, climate change and the political and policy challenges involved in managing energy supply and achieving energy security.

- Economics of renewable energy

This course gives an understanding of the economic principles and mechanisms which affect energy markets today. It covers price mechanisms, the economics of extracting energy and the cost-efficiency of renewable energy technologies. You will learn about economic instruments used by policy-makers to address environment and energy issues, economic incentives to stimulate renewable energy development and about environmental valuation.

- Environmental Policy & Risk

This course explores the legal and policy context in which renewable energy is being exploited. You will gain an understanding of international law, particularly the Law of the Sea, property rights and how these relate to different energy resources. The course also looks at regulatory issues at the international, European and UK level, which affect how energy developments are taken forward, as well as risk assessment and management in the context of renewable energy developments.

- Environmental Processes

Particularly for those without a natural science background, this course provides a broad overview of the environmental processes which are fundamental to an understanding of renewable energy resources and their exploitation. You will study energy flows in the environment, environmental disturbance associated with energy use, and an introduction to the science of climate change. You will also learn about ecosystems and ecological processes including population dynamics and how ecosystems affect and interact with energy generation.

- Renewable Technology I: Generation

This course explores how energy is extracted from natural resources: solar, biomass, hydro, wind, wave and tide. It examines how to assess and measure the resources, and the engineering solutions which have been developed to extract energy from them. You will develop an understanding of the technical challenges and current issues affecting the future development of the renewable energy sector.

- Renewable Technology II: Integration

This course explores the technical aspects of generating renewable energy and integrating it into distribution networks. You will learn about the electricity grid and how electrical power and distribution systems work. You will find out about different renewable fuel sources and end uses, and the challenges of energy storage.

- Development Appraisal

Looking at what happens when renewable energy technologies are deployed, this course examines development constraints and opportunities: policy and regulatory issues (including strategic environmental assessment, environmental impact assessment, landscape assessment, capacity issues and the planning system). It also looks at the financial aspects (valuation of capital assets, financing projects and the costs of generating electricity) and at project management.

- Development Project

This is a team project, where students have the opportunity to apply what they have learned through the other courses in relation to a hypothetical project. You have to look at a range of issues including resource assessment, site selection, development layout, consents, planning and economic appraisal, applying the knowledge and tools you have studied.

- Optional design project

For students who can demonstrate existing knowledge covered by one of the courses, there is the option of understanding a design project supervised by one of our engineers.

- Dissertation

This research project (equivalent in assessment to 4 taught courses) allows you to focus on a specific area of interest, with opportunities to collaborate with businesses and other stakeholders. You choose your dissertation subject, in discussion with your supervisor.

- Additional information

If you study at our Orkney Campus, you will also benefit from a number of activities including guest lectures and practical sessions, which help to develop your skills and knowledge in your field of study, and offer opportunities to meet developers and others involved in the renewable energy industry.

Scholarships available

We have a number of fully funded Scottish Funding Council (SFC) scholarships available for students resident in Scotland applying for Renewable Energy Development (RED) MSc. Find out more about this scholarship and how to apply http://www.hw.ac.uk/student-life/scholarships/postgraduate-funded-places.htm .

English language requirements

If your first language is not English, or your first degree was not taught in English, we’ll need to see evidence of your English language ability. The minimum requirement for English language is IELTS 6.5 or equivalent. We offer a range of English language courses to help you meet the English language requirement prior to starting your masters programme:

- 14 weeks English (for IELTS of 5.5 with no more than one skill at 4.5);

- 10 weeks English (for IELTS of 5.5 with minimum of 5.0 in all skills);

- 6 weeks English (for IELTS 5.5 with minimum of 5.5 in reading & writing and minimum of 5.0 in speaking & listening)

Distance learning students

Please note that independent distance learning students who access their studies online will be expected to have access to a PC/laptop and internet.

Find information on Fees and Scholarships here http://www.postgraduate.hw.ac.uk/prog/msc-renewable-energy-development-red-/



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The Master of Science course in Energy Engineering is aimed at students trained as general engineers with skills on the new technologies relevant to the energy conversion and its rational use. Read more
The Master of Science course in Energy Engineering is aimed at students trained as general engineers with skills on the new technologies relevant to the energy conversion and its rational use. Candidates will be required to plan, design and manage energy systems blending creative solutions with up-to-date technologies relative to energy conversion and efficiency enhancement.

At the end of the course, engineers will be good at operating in the current technological/industrial environment - i.e. a dynamic and competitive one - and sensitive to the main industry, environment and security issues and standards.

The main aim of the course is to offer an in-depth theoretical and practical understanding of the most advanced energy conversion technologies, including renewable energy generation and energy storage.

Please visit http://www.en2.unige.it for any further information.

The Course is held at Savona Campus, in the city of Savona.

WHAT WILL YOU STUDY AND FUTURE PROSPECTS

The course consists of modules that include thermo-fluid dynamics and thermo-chemical dynamics, as well as fluid machinery and energy conversion systems (co-generation, fuel cells, power plants from renewable energy sources and smart grids), traditional energy and civil engineering plants, electric networks, economics, available and emerging technologies for reducing greenhouse gas emissions and environmental monitoring.

A rising interest in and increased urge for 20/20/20 policies in Europe has resulted in a growing industrial demand for highly qualified Energy Engineers with a sound knowledge and specific skills to analyze, design and develop effective solutions in a broad range of contexts. Furthermore, in the last few years both emerging industrial countries and developing ones have increased their awareness of environmental issues and energy production and started implementing large energy engineering projects thus boosting the job opportunities worldwide. The course is aimed at students seeking high qualification in the following main fields:

Energy conversion processes from chemical, bio-chemical, thermal sources into mechanical and electrical ones

Sustainable & Distributed Energy: renewable energy (solar, geothermal, wind, hydro), fuel cells, bio-fuels, smart power grids, low emission power plants Sustainable Development: C02 sequestration, LCA analysis, biomass exploitation, Energy Audit in buildings, energy from waste, recycling, modeling and experimental techniques devoted to optimum energy management.

The MSc course work in partnership with industries and research institutes in Liguria, in Italy and abroad.

WHAT DOES THE MASTER IN ENERGY ENGINEERING OFFER TO ITS STUDENTS

In the last years both industrialization and population growth have brought to a higher demand for sustainable energy, smart energy management with reduced environmental impact. As a result the MSc Energy Engineering was born out of the need to better cope with Sustainable Development issues and progress in energy conversion technologies, in including renewable energy generation and energy storage, NZE buildings, with an increasing attention devoted to greenhouse gas emissions reduction through a multidisciplinary approach.

This MSc course is taught in English and students are supported in achieving higher English language skills. The University of Genoa set its modern campus in Savona and in the last few years, public and private funds have been invested to improve its infrastructures, sport facilities, hall of residence, library and an auditorium.

The University of Genoa and Siemens jointly developed a smart polygeneration microgrid in Savona Campus – officially commissioned on February 2014.

Since then the campus has largely generated enough power to satisfy its own needs with the help of several networked energy producers, i.e. total capacity 250Kw of electricity and 300kW of heating.

The grid includes microgasturbines, absorption chillers, a photovoltaic plant, a solar power station and electrochemical and thermal storage systems.

This huge facility together with a series of laboratories located at the Campus (e.g. Combustion Lab, Energy Hub Lab) offer the students a unique opportunity for hands-on activities, e.g. to measure and investigate the performance of real scale innovative energy systems.

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This is a 12 month full-time MSc degree course (See http://www.postgraduate.hw.ac.uk/prog/msc-marine-renewable-energy/#overview ) taught at our Orkney Campus. Read more

Overview

This is a 12 month full-time MSc degree course (See http://www.postgraduate.hw.ac.uk/prog/msc-marine-renewable-energy/#overview ) taught at our Orkney Campus. It involves studying 8 taught courses. If you can demonstrate that you have already mastered the subject, you may apply for an exemption from one of the taught courses and undertake a Design Project instead. The MSc programme is completed with a research dissertation equivalent to 4 taught courses.

For more information visit http://www.hw.ac.uk/schools/life-sciences/research/icit.htm

Distance Learning

The Marine Renewable Energy MSc/Diploma is also available for independent distance learning. For distance learners, the main difference is that you will undertake the Development Project alone rather than as part of a group. You can still obtain the full MSc in Marine Renewable Energy, or you can opt to study fewer courses, depending on your needs.

Scholarships available

We have a number of fully funded Scottish Funding Council (SFC) scholarships available for students resident in Scotland applying for Marine Renewable Energy. Find out more about this scholarship and how to apply http://www.hw.ac.uk/student-life/scholarships/postgraduate-funded-places.htm .

Programme content

The Diploma and MSc degree course involves studying the 8 taught courses outlined below. If a student can demonstrate that they have already mastered the subject, they may undertake a Development Project instead of one of these courses.

- Energy in the 21st Century
This course is designed to give you a broad understanding of the environmental, political and socio-economic context for current developments in renewable energy. The course examines the extent of current energy resources and how energy markets function. It covers some energy basics you will need for the rest of the programme (e.g. thermodynamics, efficiency conversions) as well as environmental issues associated with energy use, climate change and the political and policy challenges involved in managing energy supply and achieving energy security.

- Economics of renewable energy
This course gives an understanding of the economic principles and mechanisms which affect energy markets today. It covers price mechanisms, the economics of extracting energy and the cost-efficiency of renewable energy technologies. You will learn about economic instruments used by policy-makers to address environment and energy issues, economic incentives to stimulate renewable energy development and about environmental valuation.

- Environmental Policy & Risk
This course explores the legal and policy context in which renewable energy is being exploited. You will gain an understanding of international law, particularly the Law of the Sea, property rights and how these relate to different energy resources. The course also looks at regulatory issues at the international, European and UK level, which affect how energy developments are taken forward, as well as risk assessment and management in the context of renewable energy developments.

- Oceanography & Marine Biology
This course is designed to give you an understanding of the science of waves and tides, and how this affects efforts to exploit energy from these resources. You will also learn about marine ecosystems and how these may be impacted by energy extraction and about the challenges and impacts associated with carrying out engineering operations in the marine environment.

- Marine Renewable Technologies
You will gain an understanding of renewable energy technologies which exploit wind, wave and tidal resources. The focus is on technical design issues which developers face operating in the marine environment, as well as the logistics of installation, operations and maintenance of marine energy converters.

- Renewable Technology: Integration
This course explores the technical aspects of generating renewable energy and integrating it into distribution networks. You will learn about the electricity grid and how electrical power and distribution systems work. You will find out about different renewable fuel sources and end uses, and the challenges of energy storage.

- Development Appraisal
Looking at what happens when renewable energy technologies are deployed, this course examines development constraints and opportunities: policy and regulatory issues (including strategic environmental assessment, environmental impact assessment, landscape assessment, capacity issues and the planning system). It also looks at the financial aspects (valuation of capital asses, financing projects and the costs of generating electricity) and at project management.

- Development Project
This is a team project, where students have the opportunity to apply what they have learned through the other courses in relation to a hypothetical project. You have to look at a range of issues including resource assessment, site selection, development layout, consents, planning and economic appraisal, applying the knowledge and tools you have studied.

- Dissertation
This research project (equivalent in assessment to 4 taught courses) allows you to focus on a specific area of interest, with opportunities to collaborate with businesses and other stakeholders. You choose your dissertation subject, in discussion with your supervisor.

- Additional information
If you study at our Orkney Campus, you will also benefit from a number of activities including guest lectures and practical sessions which help to develop your skills and knowledge in your field of study, and offer opportunities to meet developers and other involved in the renewable energy industry.

English language requirements

If your first language is not English, or your first degree was not taught in English, we’ll need to see evidence of your English language ability. The minimum requirement for English language is IELTS 6.5 or equivalent. We offer a range of English language courses (http://www.hw.ac.uk/study/english.htm ) to help you meet the English language requirement prior to starting your masters programme:
- 14 weeks English (for IELTS of 5.5 with no more than one skill at 4.5);
- 10 weeks English (for IELTS of 5.5 with minimum of 5.0 in all skills);
- 6 weeks English (for IELTS 5.5 with minimum of 5.5 in reading & writing and minimum of 5.0 in speaking & listening)

Distance learning students

Please note that independent distance learning students who access their studies online will be expected to have access to a PC/laptop and internet.

Find information on Fees and Scholarships here http://www.postgraduate.hw.ac.uk/prog/msc-marine-renewable-energy/#overview

Visit the Marine Renewable Energy MSc/Diploma page on the Heriot-Watt University web site for more details!

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Rational and economic use of energy, with the least damage to the environment, is vital for the future of our planet. Achieving energy efficiency and reducing environmental pollution are increasingly important aspects of professional engineering. Read more

Rational and economic use of energy, with the least damage to the environment, is vital for the future of our planet. Achieving energy efficiency and reducing environmental pollution are increasingly important aspects of professional engineering. This course equips graduates and practicing engineers with an in-depth understanding of the fundamental issues of energy thrift in the industrial and commercial sectors.

Who is it for?

The MSc in Energy Systems and Processes consists of nine taught modules including an energy audit group project and an individual research project.

The course has been developed to provide up-to-date technical knowledge and skills required for achieving the better management of energy, designing of energy-efficient systems and processes, utilisation of renewable energy sources and the cost effective reduction and control of pollution. This knowledge can be directly applied to help various sectors of the economy in improving their competitiveness in the face of dwindling resources, probable substantial increases in unit energy costs and the urgent requirement to comply with the increasingly restrictive pollution control standards.

The course is suitable for engineering and applied science graduates who wish to embark on successful careers as environmentally aware energy professionals.

Why this course?

The MSc in Energy Systems and Thermal Processes, established in 1972, was the first of its type to be instituted in Europe, and remains the most prestigious degree in technical energy management in the UK. The course has evolved over the past 40 years from discussions with industrial experts, employers, sponsors and previous students. The content of the study programme is updated regularly to reflect changes arising from technical advances, economic factors and changes in legislation, regulations and standards. 

In addition to management, communication, team work and research skills, each student will attain at least the following outcomes from this degree course:

  • Demonstrate competence in the current concepts and theories governing energy flows, heat transfer and energy conversions
  • Demonstrate an in-depth understanding of the issues involved in the management of energy in industry and commerce, and the design of energy-efficient systems and processes
  • Effectively acquire and critically review information from various sources
  • Apply effectively learnt techniques and technologies to achieve cost-effective conservation of energy and reduction of environmental pollution in industrial/commercial applications
  • Assess the potential and viability of energy policies and projects and making informed judgement in the absence of complete data.

Informed by Industry

We have a world-class reputation for its industrial-scale research facilities and pilot-scale demonstration programmes in the energy area. Close engagement with the energy sector over the last 40 years has produced long-standing strategic partnerships with the sectors most prominent organisations including Alstom Power, BP, Cummins Power Generation, Doosan Babcock, E.ON, npower, Rolls Royce, Shell, Siemens and Total.

Our strategic links with industry ensure that all of the materials taught on the course are relevant, timely and meet the needs of organisations competing within the energy sector. This industry-led education makes our graduates some of the most desirable in the world for energy companies to recruit.

Accreditation

This MSc degree is accredited by Institution of Mechanical Engineers (IMechE).

Course details

The taught programme for the Energy Systems and Thermal Processes masters is generally delivered from October to March and is comprised of eight compulsory taught modules and one optional module to select from a choice of three. A typical module consists of five days of intensive postgraduate level structured lectures, tutorials or workshops covering advanced aspects of each subject.

Students on the part-time programme will complete all of the compulsory modules based on a flexible schedule that will be agreed with the Course Director.

Group project

The Energy Audit group project is part of the Energy Management for Industry module. It requires teams of students to carry out energy audits on selected industrial/commercial sites. Teams must produce prioritised recommendations to reduce energy costs. Each team is expected to present findings and conclusions at various stages and submit a final report for assessment. 

Part-time students are encouraged to participate in a group project as it provides a wealth of learning opportunities. However, an option of an individual dissertation is available if agreed with the Course Director.

Individual project

The individual research project allows you to delve deeper into a specific area of interest. As our academic research is so closely related to industry, it is common for our industrial partners to put forward real practical problems or areas of development as potential research topics. The individual research project component takes place between April and August.

For part-time students, it is common that their research project is undertaken in collaboration with their place of work. 

Research projects will involve designs, computer simulations, feasibility assessments, reviews, practical evaluations and experimental investigations.

Assessment

Taught modules 40%, Group projects 20%, Individual project 40%

Funding

To help students in finding and securing appropriate funding we have created a funding finder where you can search for suitable sources of funding by filtering the results to suit your needs. Visit the funding finder.

Your career

There is a considerable demand for environmentally aware energy specialists with in-depth technical knowledge and practical skills. Our industry-led education makes graduates of this program some of the most desirable in the world for recruitment by companies and organisations competing in the energy sector.

Graduates of the course have been successful in gaining employment in energy, environmental and engineering consultancies and design practices, research organisations and government departments. A number of our MSc graduates follow further research studies leading to PhD degrees at Cranfield and in other academic institutions.



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The Energy Systems and Data Analytics MSc provides an academically leading and industrially relevant study of energy systems through the lens of data analytics. Read more

The Energy Systems and Data Analytics MSc provides an academically leading and industrially relevant study of energy systems through the lens of data analytics. Advanced analytics, fuelled by big data and massive computational power, has the potential to transform how energy systems are designed, operated and maintained. You will gain the skills and knowledge to unlock the transformative potential of big energy data, and understand how it can reshape the energy sector.

About this degree

You will gain a broad understanding of energy systems as a whole, covering supply and demand, the interconnectedness and dependencies between different sectors and a multi-vector multi-sector approach to analysis. You will learn about the theory and practice of data analysis and will gain practical experience of the challenges of working with different data sets relating to energy throughout the programme and modules. 

The programme consists of five compulsory modules (75 credits), two optional modules (45 credits) and a dissertation (60 credits).

Core modules

  • Energy Systems
  • Energy Data Analytics
  • Statistics for Energy Analysis
  • Energy Analytics in the Built Environment
  • Energy and Transport Analytics

Optional modules

  • Spatial Analysis of Energy Data
  • Introduction to Systems Dynamics Modelling in the Built Environment
  • Econometrics for Energy and the Environment
  • Energy, Technology and Innovation
  • UK Energy and Environment Policy and Law
  • Smart Energy Systems: Theory, Practice and Implementation
  • Eco-innovation and Sustainable Entrepreneurship

The list of optional modules is correct for the 2018/19 academic year. Enrolment on modules is subject to availability.

Dissertation/report

All students undertake an independent research project whch culminates in a 10,000-word dissertation.

Teaching and learning

The programme is delivered through a combination of lectures, seminars, tutorials, problem-based learning and project work. Assessment is through a combination of methods including problem sets, individual assignments and coursework, group based design tasks with a report and presentation, unseen examinations and a dissertation.

Further information on modules and degree structure is available on the department website: Energy Systems and Data Analytics MSc

Careers

Graduates of the ESDA MSc will be ideally placed to gain employment as energy analysts/ data scientists in consultancies, utilities, innovative start-ups and government institutions which value expertise in energy systems and have a need for data literate analysts.

Employability

There is a strong emphasis placed on innovation throughout the programme. Based on our market research and the trends in the industry (which is increasingly driven by data) there will be a healthy demand for our graduates.

Students will also benefit from a skill set in data analytics that will be highly transferable and applicable across a range of industries and domains.

The programme has been developed with input from industry leaders. You will gain exposure to real life energy and sustainability challenges.

Why study this degree at UCL?

The MSc in Energy Systems and Data Analytics is the first programme in the UK to combine the study of energy systems with data science. The MSc is delivered by leading researchers in the UCL Energy Institute and UCL Institute for Sustainable Resources. You will benefit from their specific expertise, research communities and industry contacts (including guest lecturers drawn from the energy industry), as well as our multidisciplinary and cross-domain approach.

The UCL Energy Institute has consulted across industry to identify key skills gaps for the energy analysts that will be required by utilities, consultancies and small and medium enterprises. There is a growing need in industry for graduates who combine an understanding of energy systems with the skills and abilities to extract insights from data through the use of advanced analytics.

Research Excellence Framework (REF)

The Research Excellence Framework, or REF, is the system for assessing the quality of research in UK higher education institutions. The 2014 REF was carried out by the UK's higher education funding bodies, and the results used to allocate research funding from 2015/16.

Learn more about the scope of UCL's research, and browse case studies, on our Research Impact website.



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Renewable energy is an essential and vital resource for the world’s future, and future there is an urgent need for engineers capable of solving the industry’s complex challenges in this field. Read more

About the course

Renewable energy is an essential and vital resource for the world’s future, and future there is an urgent need for engineers capable of solving the industry’s complex challenges in this field.

Studying Renewable Energy Engineering at Brunel provides graduates with the knowledge and skills to make a strategic real-world impact in the resolution of the world’s energy problems.

Graduates from Brunel’s MSc in Renewable Energy Engineering will develop:

- The versatility and depth to deal with new, demanding and unusual challenges across a range of renewable energy issues, drawing on an understanding of all aspects of renewable energy principles including economic assessment.

- The imagination, initiative and creativity to enable them to follow a successful engineering career with national and international companies and organisations.

- Specialist knowledge and transferable skills for successful careers including, where appropriate, progression to Chartered Engineer status.

Aims

Huge business incentives, markets and a wide variety of employment opportunities throughout the world are expected with the development of renewable energy resources as a substitute for fossil fuel technology.

The purpose of the MSc programme is to help meet this demand by cultivating qualified and skilled professionals with specialist knowledge in relevant technologies within the renewable energy sector.

The primary aim is to create Master’s degree graduates with qualities and transferable skills ready for demanding employment in the renewable energy sector. These graduates will have the independent learning ability required for continuing professional development and acquiring new skills at the highest level, and the programme also establishes a strong foundation for those who expect to continue onto a PhD or industrial research and development.

Initial programme learning outcomes

The programme will provide opportunities for students to develop and demonstrate knowledge and understanding, qualities, skills and other attributes in the following areas:

Knowledge and understanding of:

1.The principles and environmental impact of renewable energy technologies, including solar (thermal and electricity), wind, tidal, wave and hydro, geothermal, biomass and hydrogen.
3. The principles of energy conversion and appropriate thermodynamic machines.
4. The heat and mass transfer processes that relate to energy systems and equipment.
5. The principles, objectives, regulation, computational methods, economic procedures, emissions trading, operation and economic impact of energy systems.
6. The diversity of renewable energy system interactions and how they can be integrated into actual energy control systems and industrial processes.

At the cognitive thinking level, students will be able to:

1. Select, use and evaluate appropriate investigative techniques.
2. Assemble and critically analyse relevant primary and secondary data.
3. Recognise and assess the problems and critically evaluate solutions to challenges in managing renewable energy projects.
4. Evaluate the environmental and financial sustainability of current and potential renewable energy activities
5. Develop a thesis by establishing the basic principles and following a coherent argument.

In terms of practical, professional and transferable skills, students will be able to:

1. Define and organise a substantial advanced investigation.
2. Select and employ appropriate advanced research methods.
3. Organise technical information into a concise, coherent document.
4. Communicate effectively both orally and in writing.
5. Design and select renewable energy equipment and systems based on specific requirements/conditions.
6. Work as part of, and lead, a team.

Course Content

The taught element of the course (September to April) includes eight modules; delivery will be by a combination of lectures, tutorials and group/seminar work. A further four months (May to September) is spent undertaking the dissertation.

Compulsory modules:

Renewable Energy Technologies I-Solar Thermal and electricity systems
Renewable Energy Technologies II-Wind, Tidal, Wave, Hydroelectricity
Renewable Energy Technologies III-Geothermal, Biomass, Hydrogen
Power Generation from Renewable Energy   
Renewable Energy Systems for the Built Environment
Energy Conversion Technologies
Environmental Legislation: Energy and Environmental Review and Audit
Advanced Heat and Mass Transfer
Dissertation

Teaching

Students are introduced to subject material, including key concepts, information and approaches, through a mixture of standard lectures and seminars, laboratory practical, field work, self-study and individual research reports. Supporting material isavailable online. The aim is to challenge students and inspire them to expand their own knowledge and understanding.

Preparation for work is achieved through the development of 'soft' skills such as communication, planning, management and team work. In addition, guest speakers from industries provide a valuable insight into the real world of renewable energy.

Many of the practical activities in which the students engage, develop into enjoyable experiences. For example, working in teams for laboratory and field work and site visits. We encourage students to develop personal responsibility and contribution throughout the course. Many elements of coursework involve, and reward, the use of initiative and imagination. Some of the projects may be linked with research in CEBER, CAPF and BIPS research centres.

1 Year Full-Time: The taught element of the course (September to April) is delivered by a combination of lectures, tutorials and group/seminar work. From May to September students undertake the dissertation.

3-5 Years Distance Learning: The programme is designed to enable you to conduct most of your studies at home, in your own time and at your own pace. Students are supplied with a study pack in the form of text books and CD-ROMs; cut-off dates for receipt of assignments are specified at the beginning of each stage. Examinations can be taken either at Brunel University London or in the country you are resident in. The dissertation is carried out in one year.

Modules are assessed either by formal examination, written assignments or a combination of the two.

Assessment

Each module is assessed either by formal examination, written assignments or a combination of the two. Cut-off dates for receipt of assignments are specified at the beginning of the academic year. Examinations are normally taken in May. The MSc dissertation project leading to submission of the MSc Dissertation is normally carried out over four months (FT students) or one year (DL students).

Special Features

Excellent facilities
We have extensive and well-equipped laboratories, particular areas of strength being in fluid and biofluid mechanics, IC engines, vibrations, building service engineering, and structural testing. Our computing facilities are diverse and are readily available to all students. The University is fully networked with both Sun workstations and PCs. Advanced software is available for finite and boundary element modelling of structures, finite volume modelling of flows, and for the simulation of varied control systems, flow machines, combustion engines, suspensions, built environment, and other systems of interest to the research groups.

About Mechanical Engineering at Brunel
Mechanical Engineering offers a number of MSc courses all accredited by professional institutes as appropriate additional academic study (further learning) for those seeking to become qualified to register as Chartered Engineers (CEng). Accrediting professional institutes vary by course and include the Institute of Mechanical Engineers (IMechE), Energy Institute (EI) and Chartered Institute of Building Services Engineers (CIBSE).

Teaching in the courses is underpinned by research activities in aerospace engineering, automotive/motorsport engineering, solid and fluid mechanics, and energy & environment. Staff generate numerous publications, conference presentations and patents, and have links with a wide range of institutions both within and outside the UK. The discipline benefits from research collaboration with numerous outside organisations including major oil companies, vehicle manufacturers, and other leading industrial firms and governmental laboratories. We have links with at least six teaching hospitals and work with universities in China, Poland, Egypt, Turkey, Denmark, Japan, Brazil, Germany, Belgium, Greece, Italy and the US.

Women in Engineering and Computing Programme

Brunel’s Women in Engineering and Computing mentoring scheme provides our female students with invaluable help and support from their industry mentors.

Accreditation

The requirement of UK-SPEC reinforces the need for a recent graduate with a Bachelor degree to take an appropriate postgraduate qualification in order to become a chartered engineer (currently, an accredited Bachelors degree does not enable the graduate to proceed to Chartered Engineer status without additional learning at M level).

This MSc program will be compliant with the further learning requirements of UK-SPEC. Accreditation will be sought from the Institute of Mechanical Engineering (IMechE) and Energy Institute. As a result, it will appeal to recent graduates who have not yet obtained the appropriate qualifications but intend to become Chartered Engineers. Most importantly, it will appeal to Mechanical, Chemical and Building Services Engineering graduates who wish to specialise in energy, or suitably experienced graduates of related subjects such as Physics.

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The Master of Science programme in Energy Engineering for an Environmentally Sustainable World (EEE-SW) is taught in English and offers a broad overview of the various technical issues related to energy and the environment. Read more

Mission and Goals

The Master of Science programme in Energy Engineering for an Environmentally Sustainable World (EEE-SW) is taught in English and offers a broad overview of the various technical issues related to energy and the environment. This special programme aims to prepare technicians capable of following and actively directing technological advances, operating effectively in a competitive and multi-disciplinary industrial context.

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

Career Opportunities

Graduates find employment in numerous industrial sectors, including industries producing and distributing energy, thermal, thermal-electric, air-conditioning and refrigeration plant design and management companies, energy management in companies or bodies with production objectives which may be far-removed energy. A Master of Science Engineer has openings in research and development as well as in activities related to the feasibility study and design of large-scale plant, innovative processes and development of technologically advanced machines and components.

For the academic year 2014-2015 prospective students with a university qualification obtained abroad can apply only for the 1st semester. This study course does not accept applications for the 2nd semester.
Applicants are required to take the GRE test (Graduate Record Examination) through ETS DI code 6939 in due time to have test scores sent to Welcome Desk Piacenza (welcome.piacenza(at)polimi.it) within the last day of the application period.

Recommended minimum GRE scores to be achieved for admission:
Verbal Reasoning: 155
Quantitative Reasoning: 155
Analytical Writing: 4.0

Only students with a Degree earned at an Italian University can apply without taking GRE test and they can also apply for admission at the 2nd semester.

Presentation

See http://www.polinternational.polimi.it/uploads/media/Energy_Engineering_01.pdf
The programme provides a mix of design, operational and management skills, with particular emphasis on system and process engineering related to the production of basic energy carriers (electricity, heat and fuels) under tight environmental constraints. Students will learn how to evaluate and solve engineering issues (thermal, environmental, mechanical, chemical, electrical) raised by energy conversion systems, as well as analyze and assess operational and maintenance issues. Particular attention will be devoted to renewable energy sources, non-conventional energy technologies, emission control, electric systems with distributed power generation, etc. Teaching is organized around 3 core aspects: modeling and simulation tools; interdisciplinary vision; problem-solving approach. The programme is taught in English.

Subjects*

1st year – 1st semester
- Advanced Mathematical methods for energy engineering
- Advanced Thermodynamics and Heat Transfer
- Fundamentals of chemical processes for energy and the environment
1st year – 2nd semester
- Turbomachinery and internal combustion engines
- Energy and environmental technologies for building systems
- Electric conversion of renewable energy sources
- Materials and manufacturing process for energy

2nd year – 1st semester
- Energy systems and low-carbon technologies
- Air pollution and control engineering
- Operation and control of machines for power generation
2nd year – 2nd semester
- Bio-energy and waste-to-energy technologies
- Smart grids and regulation for renewable energy sources
- Major independent project work

* The list and titles of the courses to be followed is undergoing a revision aimed at enhancing the focus of the programme on the connection between Energy and the Environment. This will entail a reduction of the credits devoted to manufacturing, operation and control of machines and an increase of the credits devoted to optimization methods, renewable energy, industrial ecology. The final list of courses to be taken for the Academic Year 2016-17 will be available in January 2016.

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

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

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The part-time MSc Renewable Energy Systems is the first cross-border program in Europe dealing with the future issues of alternative energy production. Read more

The part-time MSc Renewable Energy Systems is the first cross-border program in Europe dealing with the future issues of alternative energy production. Since 2005, TU Wien, Energiepark Bruck/Leitha and further partner organisations across Europe have offered this practice-oriented master’s program.

With this comprehensive education in the field of renewable energy you acquire knowledge and competence for the design of plants for the use of renewable energy sources from an economic and legal point-of-view, the operation of plants and the future assessment of environmental, technical and economic developments of renewable energy systems.

Contents

This master's program focuses on three aspects in particular: technological innovations, management of sustainable energy systems, and economic as well as legal frameworks.

  • Technological Innovations: Participants acquire a basic technical knowledge in the area of alternative energy production. The fast-changing nature and development of this sector are specifically considered. Focal points are solar energy, wind power, biomass, biogas, small hydropower stations, photovoltaics, bio fuel, and geothermal technology as well as issues, such as energy saving and energy efficiency.
  • Management of Sustainable Energy Systems: Conveys skills, such as project development, project financing, project operation, and knowledge on business management. Furthermore, participants obtain a detailed market overview on selected European countries.
  • General Economic and Legal Framework: Participants obtain knowledge on the general economic and legal frameworks of European Union as well as national directives and legal provisions of selected European countries.

Modules

  • Introduction on Renewable Energy
  • Biomass, Biofuels and Biogas
  • Solar Energy – Solar Heating and Photovoltaics
  • Geothermal Energy, Wind Power, and Small Hydro Power
  • Efficient Energy Use and Thermal Building Optimization
  • General Legal and Economical Frameworks
  • Integration of Renewable Energy Sources into the Energy System
  • Management and Soft Skills
  • Perspectives on the Use of Renewable Energy
  • Master´s Thesis

More details on the contents and modules can be found here.

Country Modules

To provide the participants with in-depth knowledge on energy markets in Europe, tailor-made country modules in selected European countries are an essential part of this MSc program. For more information in the country modules, please click here.

Target Group

Individuals within companies, organisations, and authorities who are engaged in planning, operating or evaluation of renewable energy or who are involved in financing, promotion, legal licensing, operation of facilities for the use of renewable energy or environmental issues.

Program Objectives/Goals

With the MSc Program you acquire knowledge and competence for

  • the design of plants for the use of renewable energy sources from economic and legal point-of-view
  • the operation of plants for the use of renewable energy sources,
  • the future assessment of environmental, technological and economic developments of renewable energy systems.


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