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The Laurea Magistrale (equivalent to a Master of Science) trains professionals with solid engineering foundations, a good scientific approach and a broad range of technical and applied contents. Read more

Mission and goals

The Laurea Magistrale (equivalent to a Master of Science) trains professionals with solid engineering foundations, a good scientific approach and a broad range of technical and applied contents. The level of cultural education is raised during the first year by broadening the knowledge of advanced analysis methods, which in the second year are applied in specialisation subjects and a thesis. The first year is offered in the Milano Bovisa and Lecco campuses with the same study plan (the first year is not available in the Piacenza campus, which offers only the second year). Students can choose different previously approved study plans (PSPA) in the second year. Some are offered in the Milano Bovisa campus (“Impianti e Produzione” [Production Plants and Production], “Meccatronica e Robotica” [Mechatronics and Robotics], “Metodi e Tecniche di Prototipazione Virtuale” [Methods and Techniques for Virtual Prototyping], “Motori e Turbomacchine” [Engines and Turbomachinery], “Progettazione” [Design], “Materiali e Tecnologie Innovative” [Materials and Innovative Technologies] and “Veicoli Terrestri” [Ground Vehicles]). Others are offered in the Lecco campus (“Mechanical Systems Design” and “Industrial Production”) and one in the Piacenza campus (“Macchine Utensili e Sistemi di Produzione” [Machine Tools and Production Systems]).

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

Career opportunities

Graduates with a Laurea Magistrale (equivalent to a Master of Science) in Mechanical Engineering are technicians who can independently develop the functional, construction and energy-related aspects of innovative products, processes and systems in industry and in the advanced tertiary sector. On passing the State Professional Examination, Mechanical Engineering Graduates with a Laurea Magistrale (equivalent to a Master of Science) can ask to be included in the Register of Engineers (section A).

Presentation

See http://www.polinternational.polimi.it/uploads/media/Mechanical_Engineering_04.pdf
The MSc Programme in Mechanical Engineering – Ingegneria Meccanica provides an academically challenging exposure to modern issues in advanced Mechanical Engineering.
The educational goal of the MSc Programme is to train highly qualified engineers, capable of playing different roles in the job market, by providing them with sound scientific, economic and technical competences, together with broad practical and professional skills needed for a successful career in a technologically advanced and rapidly evolving society.
The specialist in Mechanical Engineering, being involved in the design, production process and operation of products and systems, needs to develop a strong interdisciplinary background in machine design, with respect to functional requirements, dynamic and structural analysis, propulsion and engine systems, fluid mechanics, material properties and selection, manufacturing processes and production systems, operation and management of industrial plants, experimental techniques, mechatronics and industrial automation. The programme is taught in English. http://www.ccsmecc.polimi.it/en

Subjects

The 1st year is organised in the following compulsory modules: Control and Actuating Devices for Mechanical Systems, Applied Metallurgy, Energy Systems, Nonconventional Machining Processes, Machine Design, Mechanical System Dynamics, Mechanical Measurements, Configuration and Management of Production Systems.

In the 2nd year students will have the possibility to specialize the training, by choosing among the following tracks:
Milano Bovisa Campus: Production Systems, Mechatronics and robotics, Virtual prototyping, Internal Combustion Engines and Turbomachinery, Advanced Mechanical Design, Advanced Materials and Technology, Ground Vehicles.
Lecco Campus: Mechanical Systems Design, Industrial Production.
Piacenza Campus: Machine Tools and Manufacturing Systems.

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

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

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

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Gas Turbine Technology provides a comprehensive background in the design and operation of different types of gas turbines for all applications. Read more

Course Description

Gas Turbine Technology provides a comprehensive background in the design and operation of different types of gas turbines for all applications. This course is designed for those seeking a career in the design, development, operations and maintenance of power and propulsion systems. Graduates are provided with the skills that allow them to deliver immediate benefits in a very demanding and rewarding workplace and therefore are in great demand. The course is suitable for graduates seeking a challenging and rewarding career in an international growth industry.

The UK continues to lead the world in power and propulsion technology. In addition to its established aerospace role, the gas turbine is finding increasing application in power generation, oil and gas pumping, chemical processing and power plants for ships and other large vehicles.

Course overview

The course consists of approximately ten to fifteen taught modules and an individual research project.

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

- Provide the skills required for a rewarding career in the field of propulsion and power.
- Meet employer requirements for graduates within power and propulsion industries.
- Demonstrate a working knowledge and critical awareness of gas turbine performance, analysis techniques, component design and associated technologies.
- Explain, differentiate and critically discuss the underpinning concepts and theories for a wide range of areas of gas turbine engineering and associated applications.
- Be able to discern, select and apply appropriate analysis techniques in the assessment of particular aspects of gas turbine engineering.

Individual Project

You are required to submit a written thesis describing an individual research project carried out during the course. Many individual research projects have been carried out with industrial sponsorship, and have often resulted in publication in international journals and symposium papers. This thesis is examined orally in September in the presence of an external examiner.

Recent Individual Research Projects include:

- S-duct aerodynamic shape multi-objective optimisation
- Performance modelling of evaporative gas turbine cycles for marine applications
- Mechanical integrity/stress analysis of the high pressure compressor of a new engine
- High pressure turbine blade life analysis for a civilian derivative aircraft conducting military operations
- Engine performance degradation due to foulants in the environment
- Effects of manufacturing tolerances on gas turbine performance and components
- Development of a transient combustion model
- Numerical fan modelling and aerodynamic analysis of a high bp ratio turbofan engine
- Combustor modelling
- Impact of water ingestion on large jet engine performance and emissions
- Windmilling compressor and fan aerodynamics
- Neural networks based sensor fault diagnostics for industrial gas turbine engines
- Boundary layer ingestion for novel aircraft
- Multidisciplinary design optimisation for axial compressors
- Non-linear off design performance adaptation for a twin spool turbofan engine
- Engine degradation analysis and washing effect on performance using measured data.

Modules

The taught programme for the Gas Turbine Technology masters consists of seven compulsory modules and up to seven optional modules. The modules are generally delivered from October to April.

Core -

Blade Cooling
Combustors
Engine Systems
Gas Turbine Theory and Performance
Mechanical Design of Turbomachinery
Gas Turbine Simulation and Diagnostics
Turbomachinery

Optional -

Computational Fluid Dynamics
Fatigue and Fracture
Gas Turbine Applications
Jet Engine Control (only October intake)
Management for Technology
Propulsion Systems Performance and Integration
Rotating Equipment Selection

Assessment

The final assessment is based on two components of equal weight; the taught modules (50%) and the individual research project (50%). Assessment is by examinations, assignments, presentations and thesis.

Funding

A variety of funding, including industrial sponsorship, is available. Please contact us for details.

Cranfield Postgraduate Loan Scheme (CPLS) - https://www.cranfield.ac.uk/Study/Postgraduate-degrees/Fees-and-funding/Funding-opportunities/cpls/Cranfield-Postgraduate-Loan-Scheme

The Cranfield Postgraduate Loan Scheme (CPLS) is a funding programme providing affordable tuition fee and maintenance loans for full-time UK/EU students studying technology-based MSc courses.

Career opportunities

- Gas turbine engine manufacturers
- Airframe manufacturers
- Airline operators
- Regulatory bodies
- Aerospace/Energy consultancies
- Power production industries
- Academia: doctoral studies.

Further Information

For further information on this course, please visit our course webpage - http://www.cranfield.ac.uk/Courses/Masters/Gas-Turbine-Technology-option-Thermal-power

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Rotating Machinery, Engineering and Management provides a comprehensive background in the design and operation of different types of rotating equipment for power, oil, gas, marine and other surface applications. Read more

Course Description

Rotating Machinery, Engineering and Management provides a comprehensive background in the design and operation of different types of rotating equipment for power, oil, gas, marine and other surface applications. The course is designed for those seeking a career in the design, development, operation and maintenance of power systems. Graduates are provided with the skills that allow them to deliver immediate benefits in a very demanding and rewarding workplace and therefore are in great demand. This course is suitable for graduates seeking a challenging and rewarding career in an international growth industry.

Overview

Rotating machinery is employed today in a wide variety of industrial applications including oil, power, and process industries. With the continuing expansion of the applications of rotating machinery, qualified personnel are required by the increasingly large numbers of users.

English Language Requirements

If you are an international student you will need to provide evidence that you have achieved a satisfactory test result in an English qualification. The minimum standard expected from a number of accepted courses are as follows:

IELTS - 6.5
TOEFL - 92
Pearson PTE Academic - 65
Cambridge English Scale - 180
Cambridge English: Advanced - C
Cambridge English: Proficiency - C

In addition to these minimum scores you are also expected to achieve a balanced score across all elements of the test. We reserve the right to reject any test score if any one element of the test score is too low.

We can only accept tests taken within two years of your registration date (with the exception of Cambridge English tests which have no expiry date).

Structure

The course consists of approximately eight to twelve taught modules and an individual research project.

In addition to management, communication, team work and research skills, each student will attain at least the following outcomes from this degree course:
- Provide the skills required for a rewarding career in the field of propulsion and power.
- Meet employer requirements for graduates within power and propulsion industries.
- Demonstrate a working knowledge and critical awareness of gas turbine performance, analysis techniques, component design and associated technologies.
- Explain, differentiate and critically discuss the underpinning concepts and theories for a wide range of areas of gas turbine engineering and associated applications.
- Be able to discern, select and apply appropriate analysis techniques in the assessment of particular aspects of gas turbine engineering.

Modules

The taught programme for the Rotating Machinery, Engineering and Management masters consists of eight compulsory modules and up to four optional modules. The modules are generally delivered from October to April.

Core:
- Blade Cooling
- Combustors
- Engine Systems
- Gas Turbine Theory and Performance
- Management for Technology: Energy
- Mechanical Design of Turbomachinery
- Turbomachinery
- Gas Turbine Operations and Rotating Machines

Optional:
- Computational Fluid Dynamics
- Fatigue and Fracture
- Gas Turbine Simulation and Diagnostics

Individual Project

You are required to submit a written thesis describing an individual research project carried out during the course. Many individual research projects have been carried out with industrial sponsorship, and have often resulted in publication in international journals and symposium papers. This thesis is examined orally in September in the presence of an external examiner.

Recent Individual Research Projects include:
- Performance and economic study on the viability of combined cycle floating power barge
- Risk-based maintenance for azep
- Implementation of the nutating disk engine in high bypass turbofan
- Load minimization of tidal turbines
- Gas turbine airfleet maintenance case study
- Airfleet maintenance study
- Advanced bottoming cycle technology
- Cavitation simulation in centrifugal pump.

Assessment

The final assessment is based on two components of equal weight; the taught modules (50%) and the individual research project (50%). Assessment is by examinations, assignments, presentations and thesis.

Career opportunities

- Gas turbine engine manufacturers
- Airframe manufacturers
- Airline operators
- Regulatory bodies
- Aerospace/Energy consultancies
- Power production industries
- Academia: doctoral studies.

For further information

On this course, please visit our course webpage http://www.cranfield.ac.uk/Courses/Masters/Rotating-Machinery-Engineering-and-Management-Option

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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 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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Mechanical engineering plays an essential role at every level in society. Our course is for you if you’re a newly qualified or practising engineer looking to improve your expertise in specialist areas. Read more
Mechanical engineering plays an essential role at every level in society.

Our course is for you if you’re a newly qualified or practising engineer looking to improve your expertise in specialist areas.

Our MSc will enhance both your theoretical knowledge and practical skills in areas such as:
-Computational fluid dynamics
-Advanced thermofluids
-Advanced manufacture techniques
-Heat transfer

You’ll develop your academic and professional excellence. Our options cover a range of application areas – you’ll be able to specialise in your area of interest.

A combination of taught modules and project work provides an excellent platform to further your career in mechanical engineering.

How will I study?

There are core modules and options, and a supervised project. Modules are taught in the autumn and spring terms, with examination periods in January and May. Your project is undertaken over the spring term and the summer. It leads to submission of your dissertation and project presentation.

Modules are assessed via:
-Laboratory reports
-Essays
-Unseen examinations

The project is assessed by:
-An interim report
-A presentation
-A substantial dissertation

MSc project

On our Masters courses, you’ll complete a substantial MSc project, which is often practical as well as theoretical. The project is designed for you to excel in your personal and professional development and to consolidate the material covered in your modules.

It demands individual responsibility and exposes you to issues of:
-Project management
-Resourcing
-Planning
-Scheduling
-Documentation and communication
-Critical awareness and creative thinking

In Engineering and Design, project assessment can include interim reports, presentations and a dissertation. Some projects are undertaken in groups and replicate the type of professional teamwork expected in industry. Topics are generated from the academic research and industrial collaborations in our Department, and a member of faculty supervises the project.

Scholarships

Our aim is to ensure that every student who wants to study with us is able to despite financial barriers, so that we continue to attract talented and unique individuals.

Chancellor's International Scholarship (2017)
-25 scholarships of a 50% tuition fee waiver
-Application deadline: 1 May 2017

HESPAL Scholarship (Higher Education Scholarships Scheme for the Palestinian Territories) (2017)
-Two full fee waivers in conjuction with maintenance support from the British Council
-Application deadline: 1 January 2017

USA Friends Scholarships (2017)
-A scholarship of an amount equivalent to $10,000 for nationals or residents of the USA on a one year taught Masters degree course.
-Application deadline: 3 April 2017

Careers

There is a demand for highly qualified engineers worldwide.

Graduates of our courses in mechanical and automotive engineering have the choice of careers in the transportation, manufacturing, energy-supply and sustainable-energy industries, telecommunications, electronics, automotive and control.

Destinations of recent graduates include:
-Mechanical applications engineer with Maclaren
-Siemens Industrial Turbomachinery
-Rydon (construction)
-Ricardo
-Jaguar Land Rover

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The MSc in New and Renewable Energy is designed to equip our graduates with the skills required to meet the growing challenge to achieve energy and environmental sustainability through the application of new and renewable energy technologies. Read more
The MSc in New and Renewable Energy is designed to equip our graduates with the skills required to meet the growing challenge to achieve energy and environmental sustainability through the application of new and renewable energy technologies. The programme aims to enable students to develop the capacity to solve problems across the traditional Engineering boundaries and to have an appreciation of complete energy systems from source to end user, to have knowledge of the relevant technologies and to understand the interactions between them. The programme also provides students with the opportunity to develop skills in research, development, design and project management through individual and team-based project work.

Course Structure

The programme consists of four core modules to provide a solid foundation in a broad range of New and Renewable Energy technologies and three optional modules that allow students to choose more specialised study programmes that are most suited to their interests. The modules include lecture courses, a group design project and a major, individual research and development project. The course starts in September with a fundamentals module which prepares students from different backgrounds to take full advantage of the courses modules that follow and which combines lectures, tutorials and laboratory experiments.

Core Modules

-Renewable Energy Fundamentals
-Renewable Energy and Environment
-Group Design Project
-Research and Development Project

Optional Modules

Students select three optional modules. In previous years these modules have included:
-Low Carbon and Thermal Technologies
-Turbomachinery and Nuclear Power Engineering
-Energy Delivery and Network Integration
-Energy Generation and Conversion Technologies
-Energy Markets and Risk

Learning and Teaching

This is a 12-month full time degree course that starts in September with an intensive core module on engineering fundamentals and finishes at the end of August the following year, when students submit a report and have an oral examination on their chosen research project. The programme consists of four core modules to provide a solid foundation in a broad range of New and Renewable Energy technologies and three optional modules that allow students to choose study programmes which are most suited to their interests. The modules include lecture courses, a group design project and an individual research and development project.

The course starts in September the first of the core modules (Renewable Energy Fundamentals), which prepares students from different backgrounds to take full advantage of all aspects of the courses. This module consists of an intensive study programme which typically combines over 30 hours of lectures with 12 hours of tutorials and labs. Topics studied include thermodynamics, fluid mechanics, power system plant, electrical circuits and power electronics and converters. The module also introduces students to best practice research techniques.

The second core module (Renewable Energy & the Environment) typically involves 19 hours of lectures and tutorials. Assessment is through a combination of examination and a coursework.

The third core module is a group design project focused on a realistic application of renewable energy. Students gain experience of teamwork and project management, as well as the technical aspects of engineering design.

A major individual research and development project completes the core modules. This provides an open-ended challenge to each individual student, in collaboration with a staff supervisor. Regular meetings are held with the supervisor to discuss project progress and planning issues. A mid-term assessment is carried out to ensure project is on track. At the end of the project students are required to submit a final report on their work, in the style of a research paper. They are also required to prepare and to present a poster to allow an assessment to be made of their understanding and ability to present their work, plus an oral examination is held to allow detailed questions to be put to the student regarding the technical aspects of their project. Students should expect to have up to 20 hours of contact time with their supervisors plus 500 hours of research work, supported by the School’s technicians and other research workers, over the course of their research projects.

Each of the optional modules involves typically 19 hours of lectures in addition to tutorials, laboratory work and assignments.

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The Mechanical Engineering MSc is designed to offer an advanced level of study in specific aspects of mechanical engineering that are in demand from industry. Read more
The Mechanical Engineering MSc is designed to offer an advanced level of study in specific aspects of mechanical engineering that are in demand from industry. The degree comprises study in analysis and design of power machinery systems, engineering structures, vibration, control and the use of computers in advanced engineering analysis.

Degree information

You will develop an advanced knowledge of mechanical engineering and associated disciplines, alongside an awareness of the context in which engineering operates, in terms of safety, environmental, social and economic aspects. Alongside this you will gain a range of intellectual, practical and transferable skills necessary to develop careers in this field.

Students undertake modules to the value of 180 credits.

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

Core modules
-Advanced Computer Applications in Engineering
-Group Project
-Materials and Fatigue
-Vibrations, Acoustics and Control
-Project Management
-Power Transmission and Auxiliary Machinery Systems

Optional modules - one of the following subject to availability:
-Applied Thermodynamics and Turbomachinery
-Heat Transfer and Heat Systems
-New and Renewable Energy Systems

Dissertation/report
Culminating in a substantial dissertation, the research project, which often has industry input, focuses your research interests and develops high-level presentation and critical thinking skills.

Teaching and learning
This dynamic programme is delivered through a combination of lectures, seminars, tutorials and example classes all of which frequently draw upon real-life industrial case studies. Each module is assessed by coursework submission alone or a combination of examination and coursework. Some include an oral presentation of project or assignment work.

Careers

Engineering graduates with good analytical abilities are in high demand and our graduates have little difficulty gaining employment across many industries. The programme specifically aims to equip students with skills in analysis and design such that they can be employed as professional engineers in virtually any sector of the mechanical engineering industry.

Top career destinations for this degree:
-Foreign Exchange Analyst, JP Morgan
-Mechanical Engineer, Lloyds Register
-PhD Mechanical Engineering, University College London (UCL)
-Graduate Trainee Engineer, Rolls-Royce
-Mechanical Engineer, Shanghai Electric

Employability
Delivered by leading researchers from across UCL, you will definitely have plenty of opportunities to network and keep abreast of emerging ideas. Collaborating with companies and bodies such as the Ministry of Defence and industry leaders such as BAE Systems and Shell are key to our success and 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?

UCL Mechanical Engineering scored highly in the UK's most recent Research Excellence Framework survey with research in such diverse areas as Formula 1, biomedical engineering and naval architecture. The department is located in the centre of one of the most dynamic cities in the world.

The department has an international reputation for the excellence of its research which is funded by numerous bodies including: the Royal Society, the Leverhulme Trust, UK Ministry of Defence, BAE Systems, Cosworth Technology, Shell, BP, Lloyds Register Educational Trust, and many others.

The Mechanical Engineering MSc has been accredited by the Institute of Mechanical Engineers (IMechE) and the Institute of Marine Engineering, Science & Technology (IMarEST) 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.

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The Marine Engineering MSc is concerned with the design, analysis and operation of machinery and systems for merchant and naval ships and submarines. Read more
The Marine Engineering MSc is concerned with the design, analysis and operation of machinery and systems for merchant and naval ships and submarines. The programme covers a wide range of engineering subjects relevant to the development and procurement of marine engineering, and the programme features two parallel mechanical and electrical streams.

Degree information

The programme comprises study in analysis and design of propulsive systems and auxiliary equipment for the latest compliant marine vessel designs as well as the use of computers in advanced engineering analysis. Students develop an understanding of elements of engineering, alongside the skills necessary to apply their knowledge in a systematic and effective manner in a group ship design exercise and an individual project.

Students undertake modules to the value of 180 credits. The programme offers two parallel streams, mechanical and electrical.

The programme consists of four core modules (60 credits), two options (30 credits) a ship design exercise (45 credits) and an independent project (45 credits).

Core modules
-Advanced Computer Applications in Engineering
-Applied Thermodynamics and Turbomachinery
-Power Transmission and Auxiliary Machinery Systems
-Vibrations, Acoustics and Control

Optional modules
Either:
-Heat Transfer and Heat Systems (Mechanical Stream)
-Materials and Fatigue (Mechanical Stream)
OR
-Electrical Machines and Power Electronic Systems (Electrical Stream)
-Electrical Power Systems & Electrical Propulsion (Electrical Stream)

Dissertation/report
All students complete a ship design exercise, working on the design of a specific vessel, and undertake an independent research project which is either analytical or design, build and test in nature.

Teaching and learning
This dynamic programme is delivered through a combination of lectures, seminars, tutorials, coursework exercises and case studies. The taught courses are assessed through formal examination and coursework, the ship design exercise is assessed through a report and oral presentations, and the individual project is assessed through a report and presentation. Visits to the marine industry are also offered.

Careers

The Marine Engineering MSc has been accredited by the Institute of Marine Engineering, Science & Technology (IMarEST) and Institute of Engineering and Technology (IET) 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.There is currently a global shortage of well-qualified marine engineers and consequently the job prospects are good.

Top career destinations for this degree:
-PhD Marine Engineering, University College London (UCL)
-Lieutenant, Koninklijke Marine (Royal Netherlands Navy)
-Marine Engineer, Ministry of Defence (MoD)
-Propulsion and Gas Turbine Systems Manager, Government of Canada
-Safety Engineer, Ministry of Defence (MoD)

Employability
Delivered by leading researchers and academics from across UCL, students will have plenty of opportunities to network and keep abreast of emerging ideas. Collaborating with companies and bodies such as the Ministry of Defence and industry leaders such as BAE Systems and Rolls Royce is key to our success and we will encourage students to develop networks through the programme itself and through the department’s careers programme, which includes employer-led events and individual coaching. We are unique in having a close relationship with the UK MoD as well Commercial Shipping companies and students benefit through industrial lectures, ship design projects and individual projects. 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?

Despite being part of a central city campus university, UCL Mechanical Engineering has excellent laboratories, including engine labs and a wave tank.

This MSc has been selected by the UK Ministry of Defence (MoD), Royal Navy, Canadian and other navies for the advanced training of their marine engineers. It also receives students from many other major maritime nations. Run in parallel with the Naval Architecture MSc, students from both programmes work together on a comprehensive and unique ship design exercise.

The department has an international reputation for excellence and is funded by numerous bodies including the Royal Society, the Leverhulme Trust, UK MoD, BAE Systems, US Naval Research (ONR).

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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.

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The world faces major challenges in meeting the current and future demand for sustainable and secure energy supply and use. Read more
The world faces major challenges in meeting the current and future demand for sustainable and secure energy supply and use. The one-year MPhil programme in Energy Technologies is designed for graduates who want to help tackle these problems by developing practical engineering solutions, and who want to learn more about the fundamental science and the technologies involved in energy utilization, electricity generation, energy efficiency, and alternative energy.

Energy is a huge topic, of very significant current scientific, technological, environmental, political and financial interest. The complexity and rapid change associated with energy technologies necessitates engineers with a very good grasp of the fundamentals, with exposure and good understanding of all main energy sources and technologies, but also with specialization in a few areas. This is the prevailing philosophy behind this MPhil, fully consistent with the prevailing philosophy and structure of the University of Cambridge Engineering Department as a whole.

See the website http://www.graduate.study.cam.ac.uk/courses/directory/egegmpmet

Course detail

The educational target of the MPhil in Energy Technologies is to communicate the breadth of energy technologies and the underpinning science. The objectives of the course are:

1. To teach the fundamental sciences behind technologies involved in energy utilization, electricity generation, energy efficiency, and alternative energy.

2. To develop graduates with an overall view of energy engineering, while offering specialization in a selected area through a research project.

3. To prepare students for potential future PhD research.

Learning Outcomes

Students will be expected to have developed fundamental knwoledge on primary and secondary energy sources, on energy transformation, and on energy utilisation technologies. They will also have developed proficiencies in project management, in research skills, in team work, and in advanced calculation methods concerning energy technologies.

Graduates from this MPhil will be excellent candidates for doctoral study (at Cambridge and elsewhere) and for employment in a wide variety of jobs (for example: in industrial Research and Development departments; in policy-making bodies; in the utilities industry; in the manufacturing sector; in energy equipment manufacturing).

Format

The course is centred around taught courses in core areas, covering basic revision and skills needed (such as Communication and Organisational Skills, Mathematical and Computational Skills, Review of Basic Energy Concepts, and Research Topics), various energy technologies (such as Clean Fossil Fuels, Solar, Biofuels, Wind etc), and energy efficiency and systems level approaches.

Elective courses may be chosen from a broad range, which includes topics such as Turbulence, Acoustics, Turbomachinery, Nuclear Power Engineering, Solar Panels, and Energy Efficiency in Buildings. Elective courses are delivered mainly by the Department of Engineering with input from the Department of Chemical Engineering and other departments in Cambridge.

Research projects are chosen from a list offered by members of staff and are linked to the principal areas of energy research in the respective departments.

Students can expect to receive reports at least termly on the Cambridge Graduate Supervision Reporting System. They will receive comments on items of coursework, and will have access to a University supervisor for their dissertation. All students will also have personal access to the Course Director and the other staff delivering the course.

Assessment

Students taking 12 elective modules will write a short thesis (up to 10,000 words). Students taking 10 elective modules will write a long thesis (up to 20,000 words). In both cases, 10% of the marks will be assigned through a pre-submission presentation, and 10% of the marks will be assigned through a post-submission presentation.

Students will take 5 core modules, and then either 5 elective modules (and a long thesis) or 7 elective modules (and a short thesis). All core modules are examined purely by coursework. Some of the elective modules are also examined wholly or partly by coursework.

Some of the elective modules are examined wholly or partly by written examination.

At the discretion of the Examiners, candidates may be required to take an additional oral examination on the work submitted during the course, and on the general field of knowledge within which it falls.

Continuing

Students wishing to apply for continuation to the PhD would normally be expected to attain an overall mark of 70%.

How to apply: http://www.graduate.study.cam.ac.uk/applying

Funding Opportunities

There are no specific funding opportunities advertised for this course. For information on more general funding opportunities, please follow the link below.

General Funding Opportunities http://www.graduate.study.cam.ac.uk/finance/funding

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The MSc in New and Renewable Energy is designed to equip our graduates with the skills required to meet the growing challenge to achieve energy and environmental sustainability through the application of new and renewable energy technologies. Read more
The MSc in New and Renewable Energy is designed to equip our graduates with the skills required to meet the growing challenge to achieve energy and environmental sustainability through the application of new and renewable energy technologies. The programme aims to enable students to develop the capacity to solve problems across the traditional Engineering boundaries and to have an appreciation of complete energy systems from source to end user, to have knowledge of the relevant technologies and to understand the interactions between them. The programme also provides students with the opportunity to develop skills in research, development, design and project management through individual and team-based project work.

Course Structure
The programme consists of four core modules to provide a solid foundation in a broad range of New and Renewable Energy technologies and three optional modules that allow students to choose more specialised study programmes that are most suited to their interests. The modules include lecture courses, a group design project and a major, individual research and development project. The course starts in September with a month long 'fundamentals' module which prepares students from different backgrounds to take full advantage of the courses modules that follow and which combines lectures, tutorials and laboratory experiments.

Core Modules
- Renewable Energy Fundamentals
- Renewable Energy and Environment
- Group Design Project
- Research and Development Project.

Optional Modules
Students select three of the following optional modules:
- Low Carbon and Thermal Technologies
- Turbomachinery and Nuclear Power Engineering
- Energy Delivery and Network Integration
- Energy Generation and Conversion Technologies
- Energy Markets and Risk

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