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There is strong demand for engineers with a postgraduate qualification and a good range of mechanical engineering skills. This MSc in Mechanical Engineering has been designed to help you achieve Chartered Engineer (CEng) status and will develop the technical and non-technical skills needed to succeed in this industry. Read more
There is strong demand for engineers with a postgraduate qualification and a good range of mechanical engineering skills. This MSc in Mechanical Engineering has been designed to help you achieve Chartered Engineer (CEng) status and will develop the technical and non-technical skills needed to succeed in this industry.

The range of modules will enhance the depth of your knowledge, while developing the skills to manage people and projects. You will use state-of-the-art engineering analysis software, and employ appropriate analytical and computerbased techniques. Additionally, you will gain an awareness of wider issues such as environmental management and safety. Completion of a dissertation allows you to research a specific topic based on real issues that organisations face.

Staff are active in research and/or consultancy, which brings relevant case studies and context to the subjects you will study.

See the website http://courses.southwales.ac.uk/courses/583-msc-mechanical-engineering

What you will study

Modules include:
- Applied Thermodynamics
- Finite Element Analysis
- Computational Fluid Dynamics
- Heat Transfer and Combustion
- Fatigue and Fracture
- Safety, Health and Environment
- Integrated Project Planning and Management
- Dissertation

Learning and teaching methods

MSc Mechanical Engineering is delivered in two major blocks that offer an intensive but flexible learning pattern, with two entry opportunities for applicants each year (February and September). Modules are taught through lectures, tutorials and practical laboratory work.

Work Experience and Employment Prospects

Mechanical engineers work in areas as diverse as design, research and development, environmental engineering, numerical analysis, computer modelling, use of materials, and control systems. In such a competitive industry, this MSc will improve your career prospects and graduates are likely to progress to occupy senior positions in the engineering industry and related sectors.

Assessment methods

You will be continually assessed by coursework or a mixture of coursework and exams. The
dissertation has three assessment elements: a thesis, a poster presentation and an oral examination (viva voce).

Facilities

The University of South Wales has excellent facilities, and is committed to investment and refurbishment. We’ve just completed a £130m investment programme in new buildings and facilities, including significant investment in the Faculty of Computing, Engineering and Science. The University has also announced a further investment of £28m ensure that you’re using equipment and software that is state-of-the-art and industry-standard, we continually evaluate our labs and teaching spaces and regularly re-fit and re-equip them. A recent refurbishment of a number of our Civil and Mechanical Engineering labs is part of this programme of continuous enhancement of our facilities.

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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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Do you want to forge your future in the marine industry? Develop an advanced understanding of both marine engineering and naval architecture on a course that will equip you with a refined knowledge of nautical design and mechanics. Read more
Do you want to forge your future in the marine industry? Develop an advanced understanding of both marine engineering and naval architecture on a course that will equip you with a refined knowledge of nautical design and mechanics. Our accreditation means you’ll be ready to apply for Chartered Engineer status upon graduation, primed for a variety of careers in the marine industry.

You will lay strong foundations for a successful career using our extensive industry links to secure a paid, one-year work placement. You’ll distinguish yourself professionally with a degree accredited by the Royal Institution of Naval Architects (RINA), the Institute of Mechanical Engineering (IMechE) and the Institute of Marine Engineering, Science and Technology (IMarEST) on behalf of the Engineering Council.

Key features

-Progress to Chartered Engineer status - upon graduation you’ll have fulfilled the education requirements.
-Distinguish yourself professionally with a degree accredited by the Royal Institution of Naval Architects (RINA), the Institute of Mechanical Engineering (IMechE) and the Institute of Marine Engineering, Science and Technology (IMarEST) on behalf of the Engineering Council. The course fully satisfies the educational base for a Chartered Engineer (CEng).
-Increase your opportunities with a solid base in mechanical engineering and an emphasis on design, opening up a variety of possible careers.
-Lay strong foundations for a successful career using our extensive industry links to secure a paid, one-year work placement. Gain the confidence, real-world know-how and vital industry experience employers are looking for.
-Work with the latest industry-standard software, in our high specification laboratories. Both will help you develop a strong understanding of fundamental principles, while honing your skills at the same time.
-Access the support you need. The Women in Technology Network (WiTNet) is a support network for all female students in technology and science subjects where women are in a minority.

Course details

Year 1
Year 1 shares modules with the MEng courses in mechanical engineering. You’ll study design, a central theme of the course, introduced through case-study and problem-based learning, materials, mechanics, thermo-fluids, electrical principles, business and mathematics. You’ll also gain practical experience through a hands-on module in manufacturing methods.

Core modules
-THER104 Introduction to Thermal Principles
-MECH119 Skills for Design and Engineering (Marine)
-BPIE115 Stage 1 Mechanical Placement Preparation
-MECH117 Mechanics
-MECH118 Basic Electrical Principles
-A5MFT1 Mech BEng 1 MFT Session
-MATH187 Engineering Mathematics
-MATS122 Manufacturing and Materials
-MECH121PP Team Engineering (Engineering Design in Action)

Year 2
In your second year you’ll study structures, fluids and thermodynamics, control, mathematics and business. You’ll learn about the stability and propulsion of marine craft, and about the marine environment. You’ll advance your existing design skills through application within a marine context.

Core modules
-BPIE215 Stage 2 Mechanical Placement Preparation
-CONT221 Engineering Mathematics and Control
-HYFM230 Fluid Mechanics 1
-STRC203 Engineering Structures
-MECH232 Engineering Design
-THER207 Applied Thermodynamics
-STO208 Business for Engineers
-MARN203 Stability and Hydrodynamics

Optional placement year
Taking an optional placement year will provide you with valuable, paid, professional experience. A placement could lead to a company sponsoring your final year project and provide opportunities for your future employment. We’ll support you in finding a suitable position.

Core modules
-BPIE335 Mechanical Engineering Related Placement

Year 3
During this year you’ll use industry typical software and use design and computational methods to further develop your design skills. You’ll specialise in your chosen discipline of naval architecture, marine engineering and marine systems. Finally, you’ll carry out an in-depth investigation into a specialist topic of personal interest as part of your individual honours project.

Core modules
-HYFM322 Computational Fluid Dynamics
-MARN338 Naval Architecture
-MARN340 Marine Systems Engineering
-PRME307 Honours Project
-MECH340 Engineering Design
-MARN306 Marine Engineering

Final year
Your final year refines the skills you have developed over the course of your studies, and includes additional technical modules. Finally, you'll work on an interdisciplinary project, drawing on your design and engineering abilities.

Core modules
-MECH532 Applied Computer Aided Engineering
-MECH533 Robotics and Control
-MECH534 Product Development and Evaluation
-MAR528 Mechanics of MRE Structures
-PRCE513 Interdisciplinary Design
-MECH544 Data Processing, Simulation and Optimisation of Engineering Systems

Every undergraduate taught course has a detailed programme specification document describing the course aims, the course structure, the teaching and learning methods, the learning outcomes and the rules of assessment.

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Could you see yourself designing high performance bikes, working with racing car teams or producing ground breaking medical components? You could follow in the footsteps of some of our graduates and begin shaping your own exciting career in mechanical engineering. Read more
Could you see yourself designing high performance bikes, working with racing car teams or producing ground breaking medical components? You could follow in the footsteps of some of our graduates and begin shaping your own exciting career in mechanical engineering.

You will distinguish yourself professionally with a degree accredited by the Institution of Mechanical Engineers (IMechE) and the Institute of Materials, Minerals and Mining (IoM3) for Chartered Engineer status. You can apply to either of these institutions for membership as a Chartered Engineer.

Key features

-Open the door to a successful future. Our graduates have gone on to work for Ferrari, Honda, British Cycling, Rolls-Royce, Williams Grand Prix Engineering, Activa, Babcock Marine, Princess Yachts and more.
-Primed for your career: 82 per cent of our students are in a professional or managerial job six months after graduation. (Source: unistats)
-Benefit from an optional 48 week paid work placement.
-Distinguish yourself professionally with a degree accredited by the Institution of Mechanical Engineers (IMechE) and the Institute of Materials, Minerals and Mining (IoM3) for Chartered Engineer status. You can apply to either of these institutions for membership as a Chartered Engineer.
-Develop a strong foundation in mechanical engineering principles and materials science.
-Choose from specialist modules in composites engineering, design and manufacture.
-Experience modern laboratory facilities for practical work which is a core part of the degree.
-Benefit from working on industrially relevant problems within composite materials and design of composite structures.

Course details

Year 1
In Year 1, you’ll acquire a sound foundation in design, mechanics, materials, electrical principles, thermo-fluids, mathematics and business, learning by active involvement in real engineering problems. You‘ll undertake a popular hands-on module in manufacturing methods. Modules are shared with the MEng and BEng (Hons) in Mechanical Engineering and the MEng and BEng (Hons) Marine Technology.

Core modules
-MECH120 Skills for Design and Engineering (Mechanical)
-THER104 Introduction to Thermal Principles
-BPIE115 Stage 1 Mechanical Placement Preparation
-MECH117 Mechanics
-MECH118 Basic Electrical Principles
-A5MFT1 Mech BEng 1 MFT Session
-MATH187 Engineering Mathematics
-MATS122 Manufacturing and Materials
-MECH121PP Team Engineering (Engineering Design in Action)

Year 2
In Year 2, you’ll build your knowledge of composite materials in preparation for specialist modules in the final year. The central role of design integrates with other modules like structures and materials. You'll also study modules on thermodynamics, fluid mechanics, business dynamics, mathematics and control and quality management.

Core modules
-BPIE215 Stage 2 Mechanical Placement Preparation
-CONT221 Engineering Mathematics and Control
-HYFM230 Fluid Mechanics 1
-STRC203 Engineering Structures
-MECH232 Engineering Design
-MFRG208 Quality Management l
-MATS234 Materials
-THER207 Applied Thermodynamics
-STO208 Business for Engineers

Optional placement year
In Year 3, you're strongly encouraged to do a year’s work placement to gain valuable paid professional experience. We will support you to find a placement that is right for you. Our students have worked for a variety of companies from BMW Mini, Bentley, Babcock Marine to NASA. A successful placement could lead to sponsorship in your final year, an industrially relevant final year project, and opportunities for future employment.

Optional modules
-BPIE335 Mechanical Engineering Related Placement

Year 4
In Year 4, you’ll specialise in composites design, engineering and manufacture. You’ll undertake an group design project. Additional modules of study include statistics and quality management. You'll also develop your knowledge and skills through an in-depth project on a topic of your choice.

Core modules
-HYFM322 Computational Fluid Dynamics
-MFRG311 Quality Management II
-MATS347 Composites Design and Manufacture
-PRME307 Honours Project
-MATS348 Composites Engineering
-MECH340 Engineering Design

Final year
In your final year, you'll extend your existing skills in engineering design, analysis and control theory. Broaden your knowledge by studying subjects such as entrepreneurship, advanced information technology, robotics and marine renewable energy. You’ll also work in a design team with students from other engineering disciplines working on projects such as design, materials and environmental issues related to bioenergy production, gas/nuclear power stations, energy from the sea and eco villages.

Core modules
-MECH532 Applied Computer Aided Engineering
-MECH533 Robotics and Control
-MECH534 Product Development and Evaluation
-MAR528 Mechanics of MRE Structures
-PRCE513 Interdisciplinary Design
-MECH544 Data Processing, Simulation and Optimisation of Engineering Systems

Every undergraduate taught course has a detailed programme specification document describing the course aims, the course structure, the teaching and learning methods, the learning outcomes and the rules of assessment.

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Fields of research include. Read more

Program Overview

Fields of research include: acoustics; aerodynamics and fluid mechanics; automatic controls; robotics and industrial automation; energy conversion, combustion, thermodynamics and heat transfer; vibrations and space dynamics; solid mechanics; bioengineering and biomechanics; design and manufacturing processes; industrial engineering, fuel cells, micro-electromechanical systems, mechatronics, and CAD; and naval architecture. Applicants for graduate degrees may be considered for appointment as research assistants, teaching assistants, or markers in the Department. Courses are selected in consultation with faculty.

Quick Facts

- Degree: Master of Applied Science
- Specialization: Mechanical Engineering
- Subject: Engineering
- Mode of delivery: On campus
- Program components: Coursework + Thesis required
- Faculty: Faculty of Applied Science

Program Requirements

The Master of Applied Science (M.A.Sc.) is a graduate-level study program that includes a research investigation and the writing of a thesis. Requirements for the M.A.Sc. include satisfactory completion of 30 credits of graduate-level courses (up to 6 credits may be at the undergraduate level in courses numbered 300 to 499), original research under the supervision of a faculty member, and a thesis. The thesis is assigned 6 to 12 credits and is counted as part of the coursework requirement. A typical completion time for the M.A.Sc. is 24 months. Subject to satisfactory progress and acceptance by a faculty supervisor, a successful M.A.Sc. graduate may transfer to a course of studies leading to the Ph.D.

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This course is designed for students from a mathematical background who wish to apply their skills to understanding the complex behaviour of Earth's atmosphere and oceans. Read more
This course is designed for students from a mathematical background who wish to apply their skills to understanding the complex behaviour of Earth's atmosphere and oceans. This is an exciting interdisciplinary subject, of increasing importance to a society facing climate change.

The focus of the course is on analysing the equations of fluid dynamics and thermodynamics, via mathematical and numerical modelling. Training is thus offered in both modern applied mathematics and atmosphere-ocean science, combining teaching resources from both the School of Mathematics and the School of Earth and Environment. The latter are provided by members of the School's Institute for Climate and Atmospheric Science, part of the National Centre for Atmospheric Science. Only a handful of UK universities are positioned to offer similar interdisciplinary training.

Two-thirds of the course consists of taught modules involving lectures and some computer workshops. Beyond a compulsory core of atmosphere-ocean fluid dynamics, students may choose options from applied maths (e.g., wave and stability theory), atmosphere-ocean science (e.g., climate change processes, weather forecasting), numerical methods and scientific computation. The final third of the course consists of an intensive summer project, in which students conduct an in-depth investigation of a chosen subject related to the course.

Careers
Students will be prepared for postgraduate research in applied mathematics or atmosphere-ocean science, or employment in the environmental sector.

However, given the interdisciplinary nature of the programme, graduates will have expertise and skills in a number of different areas, and should be attractive to wider range of employers.

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Society urgently needs experts with a multidisciplinary education in atmospheric and Earth System sciences. Climate change and issues of air quality and extreme weather are matters of global concern, but which are inadequately understood from the scientific point of view. Read more
Society urgently needs experts with a multidisciplinary education in atmospheric and Earth System sciences. Climate change and issues of air quality and extreme weather are matters of global concern, but which are inadequately understood from the scientific point of view. Not only must further research be done, but industry and business also need environmental specialists with a strong background in natural sciences. As new regulations and European Union directives are adopted in practice, people with knowledge of recent scientific research are required.

Upon graduating from the Programme you will have competence in:
-Applying experimental, computational and statistical methods to obtain and analyse atmospheric and environmental data.
-Knowledge applicable to solving global challenges such as climate change, air pollution, deforestation and issues related to water resources and eutrophication.
-Making systematic and innovative use of investigation or experimentation to discover new knowledge.
-Reporting results in a clear and logical manner.

The University of Helsinki will introduce annual tuition fees to foreign-language Master’s programmes starting on August 1, 2017 or later. The fee ranges from 13 000-18 000 euros. Citizens of non-EU/EEA countries, who do not have a permanent residence status in the area, are liable to these fees. You can check this FAQ at the Studyinfo website whether or not you are required to pay tuition fees: https://studyinfo.fi/wp2/en/higher-education/higher-education-institutions-will-introduce-tuition-fees-in-autumn-2017/am-i-required-to-pay-tuition-fees/

Programme Contents

The six study lines are as follows:
Aerosol Physics
Aerosol particles are tiny liquid or solid particles floating in the air. Aerosol physics is essential for our understanding of air quality, climate change and production of nanomaterials. Aerosol scientists investigate a large variety of phenomena associated with atmospheric aerosol particles and related gas-to-particle conversion using constantly improving experimental, theoretical, model-based and data analysis methods. As a graduate of this line you will be an expert in the most recent theoretical concepts, measurement techniques and computational methods applied in aerosol research.

Geophysics of the Hydrosphere
Hydrospheric geophysics studies water in all of its forms using physical methods. It includes hydrology, cryology, and physical oceanography. Hydrology includes the study of surface waters such as lakes and rivers, global and local hydrological cycles as well as water resources and geohydrology, the study of groundwater. Cryology focuses on snow and ice phenomena including glacier mass balance and dynamics, sea ice physics, snow cover effects and ground frost. Physical oceanography covers saline water bodies, focusing on describing their dynamics, both large scale circulation and water masses, and local phenomena such as surface waves, upwelling, tides, and ocean acoustics. Scientists study the hydrosphere through field measurements, large and small scale modelling, and formulating mathematical descriptions of the processes.

Meteorology
Meteorology is the physics of the atmosphere. Its best-known application is weather forecasting, but meteorological knowledge is also essential for understanding, predicting and mitigating climate change. Meteorologists study atmospheric phenomena across a wide range of space and time scales using theory, model simulations and observations. The field of meteorology is a forerunner in computing: the development of chaos theory, for example, was triggered by the unexpected behaviour of a meteorological computer model. Meteorology in ATM-MP is further divided into dynamic meteorology and biometeorology. Dynamic meteorology is about large-scale atmospheric dynamics, modelling and observation techniques, whereas biometeorology focuses on interactions between the atmosphere and the underlying surface by combining observations and modelling to study the flows of greenhouse gases and energy with links to biogeochemical cycles, for example. As a graduate of the meteorology line, you will be an expert in atmospheric phenomena who can produce valuable new information and share your knowledge.

Biogeochemical Cycles
Biogeochemistry studies the processes involved in cycling of elements in terrestrial and aquatic ecosystems by integrating physics, meteorology, geophysics, chemistry, geology and biology. Besides natural ecosystems, it also studies systems altered by human activity such as forests under different management regimes, drained peatlands, lakes loaded by excess nutrients and urban environments. The most important elements and substances studied are carbon, nitrogen, sulphur, water and phosphorus, which are vital for ecosystem functioning and processes such as photosynthesis. Biogeochemistry often focuses on the interphases of scientific disciplines and by doing so, it also combines different research methods. It treats ecosystems as open entities which are closely connected to the atmosphere and lithosphere. You will thus get versatile training in environmental issues and research techniques. As a graduate of this line you will be an expert in the functioning of ecosystems and the interactions between ecosystems and the atmosphere/hydrosphere/lithosphere in the context of global change. You will have knowledge applicable for solving global challenges such as climate change, air pollution, deforestation and issues related to water resources and eutrophication.

Remote Sensing
Remote sensing allows the collection of information about the atmosphere, oceans and land surfaces. Various techniques are applied for monitoring the state and dynamics of the Earth system from the ground, aircraft or satellites. While Lidar and radar scan from the surface or mounted on aircraft, instruments on polar orbiting or geostationary satellites permit measurements worldwide. In atmospheric sciences remote sensing has found numerous applications such as observations of greenhouse and other trace gases, aerosols, water vapour, clouds and precipitation, as well as surface observations, for example of vegetation, fire activity, snow cover, sea ice and oceanic parameters such as phytoplankton. Synergistic satellite data analysis enables the study of important processes and feedback in the climate system. Remote sensing advances climate research, weather forecasting, air quality studies, aviation safety and the renewable energy industry. As a graduate of the remote sensing line you will have broad expertise in the operational principles of remote sensing instruments as well as methods of data collection, analysis and interpretation.

Atmospheric Chemistry and Analysis
Atmospheric chemistry studies the composition and reactions of the molecules that make up the atmosphere, including atmospheric trace constituents and their role in chemical, geological and biological processes, including human influence. The low concentrations and high reactivity of these trace molecules place stringent requirements on the measurement and modelling methods used to study them. Analytical chemistry is the science of obtaining, processing, and communicating information about the composition and structure of matter and plays an essential role in the development of science. Environmental analysis consists of the most recent procedures for sampling, sample preparation and sample analysis and learning how to choose the best analytical methods for different environmental samples. Physical atmospheric chemistry studies focus on the reaction types and reaction mechanisms occurring in the atmosphere, with emphasis on reaction kinetics, thermodynamics and modelling methods. As a graduate of this line you will have understanding of the chemical processes of the atmosphere and the latest environmental analytical methods, so you will have vital skills for environmental research.

Programme Structure

The basic degree in the Programme is the Master of Science (MSc). The scope of the degree is 120 credits (ECTS). As a prerequisite you will need to have a relevant Bachelor’s degree. The possible major subjects are Physics, Meteorology, Geophysics, Chemistry, and Forest Ecology. The programme is designed to be completed in two years. Studies in ATM-MP consist of various courses and project work: lecture courses, seminars, laboratory work and intensive courses.

Your first year of studies will consist mainly of lecture courses. During the second year, you must also participate in the seminar course and give a presentation yourself. There is also a project course, which may contain laboratory work, data analysis, or theoretical or model studies. You will have to prepare a short, written report of the project. There are also several summer and winter schools as well as field courses for students in the Programme. Many of the courses take place at the Hyytiälä Forestry Field Station in Southern Finland. The intensive courses typically last 5–12 days and include a concise daily programme with lectures, exercises and group work.

Career Prospects

There is a global need for experts with multidisciplinary education in atmospheric and environmental issues. Governmental environmental agencies need people who are able to interpret new scientific results as a basis for future legislation. Industry, transportation and businesses need to be able to adapt to new regulations.

As a Master of Science graduating from the Programme you will have a strong background of working with environmental issues. You will have the ability to find innovative solutions to complex problems in the field of environmental sciences, climate change and weather forecasting. Graduates of the Programme have found employment in Meteorological Institutes and Environmental Administration in Finland and other countries, companies manufacturing instrumentation for atmospheric and environmental measurements and analysis, and consultancy companies. The Master's degree in ATM-MP also gives you a good background if you intend to proceed to doctoral level studies.

Internationalization

The Programme offers an international study environment with more than 30% of the students and teaching staff coming from abroad.

The ATM-MP is part of a Nordic Nordplus network in Atmosphere-Biosphere Studies, which gives you good opportunities to take courses currently in fourteen Nordic and Baltic universities. There are also several Erasmus agreements with European universities. The PanEurasian Experiment (PEEX) project provides you with opportunities to carry out part of your studies especially in China and Russia.

Research Focus

All the units teaching in the Programme belong to the National Centre of Excellence (FCoE) in Atmospheric Science – From Molecular and Biological processes to the Global Climate (ATM), which is a multidisciplinary team of the Departments of Physics, Forest Sciences and Chemistry at the University of Helsinki, the Department of Applied Physics at the University of Eastern Finland (Kuopio) and the Finnish Meteorological Institute.

The main objective of FCoE ATM is to quantify the feedbacks between the atmosphere and biosphere in a changing climate. The main focus of the research is on investigating the following topics:
1. Understanding the climatic feedbacks and forcing mechanisms related to aerosols, clouds, precipitation and biogeochemical cycles.
2. Developing, refining and utilising the newest measurement and modelling techniques, from quantum chemistry to observations and models of global earth systems.
3. Creating a comprehensive understanding of the role of atmospheric clusters and aerosol particles in regional and global biogeochemical cycles of water, carbon, sulphur, nitrogen and their linkages to atmospheric chemistry.
4. Integrating the results in the context of understanding regional and global Earth systems.

In addition to the research focus of FCoE, current research in hydrospheric geophysics at Helsinki University has an emphasis on cryology, with a focus on the effect of aerosols on Indian glaciers, the impact of climate change on the Arctic environment, the dynamics of the Austfonna ice cap in Svalbard, and the winter season in the coastal zone of the Baltic Sea.

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This course is designed to respond to a growing shortage of workforce in mechanical engineering sectors. It intends to equip our students with relevant and up-to-date knowledge and skills for their engineering competencies and careers. Read more

Why take this course?

This course is designed to respond to a growing shortage of workforce in mechanical engineering sectors. It intends to equip our students with relevant and up-to-date knowledge and skills for their engineering competencies and careers. Students have a chance to broaden and deepen their knowledge in wide range of mechanical engineering subjects. This enables our students to undertake an advanced treatment of core mechanical engineering disciplines such as design and critical evaluation of structural integrity, computation fluid dynamics, advanced materials, energy and control systems.

What will I experience?

On this course you can:

Use simulation and modelling application software for virtual design and manufacturing
Utilise our strong links with companies and investigate real industrial problems to enhance your understanding of the profession
Tie in the topic of your individual project with one of our research groups and benefit from the expertise of our actively researching academics

What opportunities might it lead to?

This course has been accredited by the Institution of Mechanical Engineers (IMechE) and Institution of Engineering and Technology (IET), meeting the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). It will provide you with some of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng).

Here are some routes our graduates have pursued:

Design
Research and development
Product manufacture
Project management

Module Details

You will study several key topics that will help equip you to work as a mechanical engineer in a broad spectrum of mechanical engineering business activity management, research, design and development roles. You will also complete a four-month individual project tailored to your individual interests that can take place in our own laboratories or, by agreement, in industry.

Here are the units you will study:

Structural Integrity: Contemporary approaches are applied to the evaluation of mixed mode fracture and fatigue failure. Dynamic plastic responses of structures and the performance of composite structures are evaluated.

Industrial Control Systems: This unit covers mathematical representation of control system models is developed principally using Laplace transforms. System behaviour and simulation is analysed with practical case studies, leading to control system specifications.

Advanced Materials: This unit is designed to deal with a wide range of advanced materials for engineering applications. Teaching will address analytical and numerical methods to assess the strength, stiffness, toughness, non-linearity behaviours, vibration and failures of engineering materials for component and structure design.

Energy Systems: This unit is designed to study the principles and techniques of operation of thermodynamics and combustion systems, as well as the provision and management of energy. The current and future requirements and trends in energy production and consumption are addressed.

Structural Application of Finite Elements: The use of finite element analysis techniques and software applied to structural problems is developed. Modelling with both isotropic and orthotropic materials is investigated, as well as such topics as cracking in dissimilar materials and composite laminates.

Computational Fluid Dynamics: A practical case study analysis approach is used for model formulation and CFD simulation. Fundamental principles are used to appraise the results of CFD analysis of problems with industrial applications.

Individual Project: A strong feature of the course is the individual project, which comprises a third of the course. We encourage students to undertake projects in industrial companies, but we can also use our extensive resources and staff skills to undertake projects within the University.

Programme Assessment

You will be taught through a mixture of lectures, seminars, tutorials (personal and academic), laboratory sessions and project work. The course has a strong practical emphasis with a significant amount of your time spent our laboratories. We pride ourselves on working at the leading-edge of technology and learning practices.

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

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

Student Destinations

The demand for more highly skilled mechanical engineers is always present and it is generally accepted that there is a current shortage of engineers.

When you graduate from this course you could find employment in a wide range of mechanical engineering-based careers, such as design, research and development and manufacturing. You could work for a large company, in the Armed Forces or in one of the many small companies within this sector. You could even start your own specialist company.

Roles our graduates have taken on include:

Mechanical engineer
Product design engineer
Aerospace engineer
Application engineer

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This programme (See http://www.postgraduate.hw.ac.uk/prog/msc-advanced-mechanical-engineering/ ) aims to develop the knowledge and skills of a Bachelor’s-level graduate Mechanical Engineering to Masters level through advanced teaching, design work and research. Read more

Overview

This programme (See http://www.postgraduate.hw.ac.uk/prog/msc-advanced-mechanical-engineering/ ) aims to develop the knowledge and skills of a Bachelor’s-level graduate Mechanical Engineering to Masters level through advanced teaching, design work and research. As such it is also an opportunity for candidates from a different Engineering background to develop key Mechanical Engineering knowledge and skills required for their professional development. A key objective of the programme is to be an accredited route to becoming Chartered Engineer.

This programme makes use of masters-level courses in the Energy Sciences and Manufacture & Design complemented with specialist courses from relevant MSc courses offered by the institute. We have seen a growing need for an advanced mechanical engineering programme at the request of applicants, and our industry partners. This programme has been specifically developed to meet this need and to encourage students of this field into further learning.

The Scottish Funding Council has made available 20 scholarships covering fees only to students with Scottish backgrounds. 6 of these places are reserved for applicants to this programme in the first instance. The remaining places are spread over all our Energy based MSc programmes. There is no separate application process for this. If you are eligible, you will be considered automatically. You will be notified through the summer if you have been selected.

Programme content

Semester One - Mandatory
- B81PI Professional and Industrial Studies
This course is specifically designed to meet the master’s level outcome requirements in the areas of professional development and practice for chartered engineering status. This multi-disciplinary course uses industrial speakers and speakers from those in the university involved in bridging the gap between academia and industrial application.

- B51GS Specialist Engineering Technologies 1
The first of the specialist engineering technologies courses is based on computational fluid dynamics and assessed by a group project

Optional (Choose two)
- B51DE Engineering Design
In this course students interact with companies in a real life small R&D project supplied by the industrial partners. Working in teams, the students have to manage the design of a prototype, product or system and interact with the industrial contact putting into practice problem-solving skills from other engineering topics studied elsewhere in the programme.

- B51EK Fluids 1
Fluid mechanics applied to aerodynamics, including ideal flows, boundary layers, and aerofoils and their use for analysis and design purposes.

- B51EM Advanced Mechanics of Materials 1
Advanced classical mechanics including 3D stress and strain with particular application to thin walled vessels. Fatigue analysis and design for fatigue limit.

- B51EO Dynamics 1
To provide students with a thorough understanding of vibration theory and an appreciation of its application in an engineering environment

- B51EQ Thermodynamics 1
Thermodynamic cycles including heat engines and reverse heat engines and means of evaluating best performance.

- G11GA Flame Appraisal
Introduction to the stages required for evaluating an oilfield for production. This covers geological considerations and fluid flow from oil bearing rock.

Semester Two – Mandatory

- B81EZ Critical Analysis and Research Preparation
This course provides research training and addresses literature review skills, project planning, data analysis and presentation with a focus to critically discuss literature, and use data to support an argument.

- B51HB Failure Accident Analysis
To acquaint students with the potential causes of material, structure or component failure; framework under which a failure or forensic engineering investigation should be carried out and give them the opportunity to work case studies through from information-gathering to preparation of reports and an awareness of fire and explosion engineering.

- B51GT Specialist Engineering Technologies 2
To present advanced theory and practice in important or emerging areas of technology including non-linear final element materials to include contact mechanics, design of components subjected to high stress applications.

Optional (Choose one)
- B51EL Fluids 2
To provide a methodology for analysing one-dimensional compressible flow systems.

- B51EN Advanced Mechanics of Materials 2
To provide students with an opportunity to: carry out advanced analyses of mechanics of materials problems; analyse mechanics of materials where time is a significant additional variable; use final element analysis for cases involving viscoelasticity and complex geometry
engage with the findings of recent research in a mechanics of materials topic

- B51EP Dynamics 2
To provide students with a thorough understanding of control theory and an appreciation of the subject of environmental acoustics and passive noise control

- B51ER Thermodynamics 2
Investigation of heat transfer mechanisms with a view to the design of effective heat exchangers for given operating conditions. The study of radiation heat transfer and combustion equilibrium.

- B51DF Engineering Manufacture
To provide the student with a detailed understanding of the importance and integration of advanced manufacturing technology and manufacturing systems within the context of product engineering. On completion, the students should have acquired a detailed understanding of the product development process from initial conception through to product support as well as appreciate the impact of each stage of the process on the business and organisationally with respect to information dependence and manufacturing processes employed.

- G11GD Flame Development
A continuation of Flame Appraisal, this course looks at the well-head arrangement for oil extraction. This is an introduction to drilling engineering and the techniques required for oil extraction.

Semester 3 – Mandatory

- B51MD Masters Dissertation
An individual project led by a research active member of staff on a current research theme with the aim of leading to the production of a journal article.

Find information on Fees and Scholarships here http://www.postgraduate.hw.ac.uk/prog/msc-advanced-mechanical-engineering/

Scholarships available

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

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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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This programme enables students to work effectively in an engineering design role, whether that role concerns the design of products, processes or systems, at an overall or detail level. Read more
This programme enables students to work effectively in an engineering design role, whether that role concerns the design of products, processes or systems, at an overall or detail level. A balance of theory and practice is applied to the solving of real engineering design problems. All projects meet the product design requirements of one of our many co-operating companies.

Core study areas include structural analysis, engineering management and business studies, computer aided engineering, product design and human factors, engineering design methods, sustainable product design, the innovation process and project management, sustainable development: the engineering context and a project.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/mechanical-manufacturing/engineering-design/

Programme modules

Compulsory Modules:
- Structural Analysis
- Engineering Management and Business Studies
- Computer Aided Engineering
- Product Design and Human Factors
- Engineering Design Methods
- Sustainable Product Design
- The Innovation Process and Project Management
- Sustainable Development: The Engineering Context
- Project

Careers and further study

Engineering design related jobs in product, process and system design environments, providing project management and communication skills and direct technical input. Graduates may also study for an MPhil or PhD with the School.

Why Choose Mechanical and Manufacturing Engineering at Loughborough?

The School of Mechanical and Manufacturing Engineering is a leader in technological research and innovation, with extensive national and international industrial links, and a long standing tradition of excellent teaching.

Our Industrial Advisory Committee, comprising of engineers at senior levels in the profession, ensures that our programmes contain the optimal balance of subjects and industrial relevance, with our programmes accredited by the Institution of Mechanical Engineers, Institution of Engineering and Technology and Institution of Engineering Designers.

- Facilities
The School has laboratories devoted to disciplines such as; dynamics and control, automation, fluid mechanics, healthcare engineering, internal combustion engines, materials, mechatronics, metrology, optical engineering, additive manufacturing, sports engineering, structural integrity and thermodynamics.

- Research
The School has a busy, multi-national community of well over 150 postgraduate research students who form an important part of our internationally recognised research activities.
We have seven key research centres (Electronics Manufacture, Intelligent Automation, Regenerative Medicine Embedded Intelligence, High Efficiency SCR for Low Emission Vehicles and High Value Manufacturing Catapult Centre) and we are a lead governing partner in the newly formed UK Manufacturing Technology Centre.

- Career prospects
90% of our graduates were in employment or further study within six months of graduating. Our graduates go on to work with companies such as Airbus, BAE Systems, Caterpillar, EDF Energy, Ford, IBM, Jaguar Land Rover, Millbrook Proving Ground, Rolls Royce and Tata Steel.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/mechanical-manufacturing/engineering-design/

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This programme has been developed to meet the growing need for postgraduate skills within the engineering industry, and the demand for professional development for graduate engineers. Read more
This programme has been developed to meet the growing need for postgraduate skills within the engineering industry, and the demand for professional development for graduate engineers. The programme integrates the mechanical engineering subjects with key generic skills in management and research methods. This approach will help to develop your critical thinking skills as a future engineering manager, or technical specialist enabling you to effectively analyse technical and management issues. The University of Hertfordshire has a worldwide reputation for excellence in applied mechanical engineering. This international reputation will give you the opportunity to study with graduates from universities worldwide. You will benefit from the expertise of guest speakers from industry where relevant and appropriate.

The programme will:
-Provide education and experience to support your professional employment and career development within the industry
-Focus on the links between engineering analysis and design and supporting management skills management
-Provide a blend of knowledge and application experience through case studies and project work
-Equip you with the theory and practice of relevant subjects, technologies and analytical tools to provide solutions for mechanical and related manufacturing problems

Why choose this course?

-The School has over 50 years' experience of teaching mechanical engineering and has established an excellent international reputation in this field
-We offer extensive lab facilities for engineering students as well as the latest software packages and windtunnels
-This MSc combines mechanical engineering subjects with key management and research methods

Professional Accreditations

Accredited for Chartered Engineer (CEng) status by the Institution of Engineering and Technology (IET) and by the Royal Aeronautical Society (RAeS).

Careers

This programme will help you to develop your critical thinking skills as a future engineering manager or technical specialist as it will enable you to effectively analyse technical and management issues. This blend of technical and managerial content is invaluable in job applications as well as helping to fast-track your career in the industry.

Teaching methods

The School of Engineering and Technology has a reputation for innovation in teaching and learning, where nearly all MSc modules are delivered through a combination of traditional face-to-face teaching and backup tutorial's using the University's StudyNet web based facility. StudyNet allows students to access electronic teaching and learning resources, and conduct electronic discussion's with staff and other students. A heavy emphasis is placed on theory and practice, and AADE has a policy of using industrial standard software wherever possible. AADE also operate an open access laboratory, and computer policy, that will help students complete coursework and assignments, at a scheduled pace and on time.

Structure

Modules
-Advanced Thermodynamics & Thermal Systems
-CFD Techniques
-Control of Engineering Systems
-Dynamics and Performance of Mechanical Systems
-FEA & Applications
-MSc Project
-Operations Management
-Operations Research
-Quality Reliability & Maintenance

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NOTE Are you a student from outside the EU? If you are an international student we have designed a version of this award especially for you! It is called the Extended International Master in Mechanical Engineering. Read more
NOTE Are you a student from outside the EU? If you are an international student we have designed a version of this award especially for you! It is called the Extended International Master in Mechanical Engineering. It includes an extra semester of preliminary study to prepare you for postgraduate learning in the UK. We strongly recommend that all international students take this option as it is proven to improve your chances of success. Take a look at this alternative course here.

Engineering is a major wealth creator for the UK and many other economies worldwide. Highly qualified engineers command a high salary and are much sought after. This course will provide you with significant skills in the major engineering functions allowing you to work in a senior technical or project management role within industry.

Course content

The course consists of 8 taught modules plus a major personal project leading to a written thesis. The taught modules cover the broad range of activities involved in designing and validating new products and machinery. You will study topics such as solid and surface modelling, rapid prototyping, Finite Element Analysis, advanced materials and thermodynamics. The subject area of your final thesis can be selected to suit your own aspirations and interests. You will be assigned a supervisor with whom you will work closely to develop an academically challenging portfolio of work.

Core modules are:
-Research Methods & Project Management
-Design Technologies for Masters
-Energy Management
-Structural Integrity
-Advanced Engineering Materials
-Applied Structural Integrity
-MSc

Project Option Modules are:
-Industrial Robotics & Control
-Control System
-Sustainable Design & Manufacture
-Industrial Placement

This course can be completed within 1 year. However this timescale is dependent on students starting the course in September, passing all modules, undertaking their project during the summer semester and experiencing no other delays (such as health issues). Many students choose to delay their project start and enjoy a well-deserved summer break to ‘re-charge their batteries’ which also has academic benefits. In this case a more realistic duration is 15 months.

Accreditation

Accredited by the Institute of Mechanical Engineers and the Institution of Engineering and Technology on behalf of the Engineering Council (partial CEng). The MSc will meet, in part, the exemplifying academic benchmark requirements for registration as a Chartered Engineer. Accredited MSc graduates who also have a BEng(Hons) accredited for CEng will be able to show that they have satisfied the educational base for CEng registration.

Employment opportunities

Upon graduation you will be ideally placed to work in a manufacturing or engineering company at a senior level working towards Chartered (CEng) status. If you prefer the course also gives a good grounding in research techniques which could allow you to continue your personal research interests to PhD level.

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