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Masters Degrees (Finite Element)

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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Computer Modelling and Finite Elements in Engineering Mechanics at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Computer Modelling and Finite Elements in Engineering Mechanics at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

Swansea University has been at the forefront of international research in the area of computational engineering. Internationally renowned engineers at Swansea pioneered the development of numerical techniques, such as the finite element method, and associated computational procedures that have enabled the solution of many complex engineering problems. As a student on the Master's course in Computer Modelling and Finite Elements in Engineering Mechanics, you will find the course utilises the expertise of academic staff to provide high-quality postgraduate training.

Key Features: Computer Modelling and Finite Elements in Engineering Mechanics

Computer simulation is now an established discipline that has an important role to play in engineering, science and in newly emerging areas of interdisciplinary research.

Using mathematical modelling as the basis, computational methods provide procedures which, with the aid of the computer, allow complex problems to be solved. The techniques play an ever-increasing role in industry and there is further emphasis to apply the methodology to other important areas such as medicine and the life sciences.

This Computer Modelling and Finite Elements in Engineering Mechanics course provides a solid foundation in computer modelling and the finite element method in particular.

The Zienkiewicz Centre for Computational Engineering, within which this course is run, has excellent computing facilities, including a state-of-the-art multi-processor super computer with virtual reality facilities and high-speed networking.

Modules

Modules on the Computer Modelling and Finite Elements in Engineering Mechanics course can vary each year but you could expect to study:

Reservoir Modelling and Simulation

Solid Mechanics

Finite Element Computational Analysis

Advanced Fluid Mechanics

Computational Plasticity

Fluid-Structure Interaction

Nonlinear Continuum Mechanics

Computational Fluid Dynamics

Dynamics and Transient Analysis

Computational Case Study

Communication Skills for Research Engineers

Numerical Methods for Partial Differential Equations

Accreditation

The MSc Computer Modelling and Finite Elements in Engineering Mechanics course is accredited by the Joint Board of Moderators (JBM).

The Joint Board of Moderators (JBM) is composed of the Institution of Civil Engineers (ICE), the Institution of Structural Engineers (IStructE), the Chartered Institution of Highways and Transportation (CIHT), and the Institute of Highway Engineers (IHE).

The MSc Computer Modelling and Finite Elements in Engineering Mechanics degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

The MSc Computer Modelling and Finite Elements in Engineering Mechanics degree has been accredited by the JBM under licence from the UK regulator, the Engineering Council.

Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). An accredited degree will provide you with some or all of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng). Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.

Facilities

Our new home at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.

Hardware includes a 450 cpu Cluster, high-end graphics workstations and high-speed network links. Extensive software packages include both in-house developed and 'off-the-shelf' commercial.

Links with Industry

The Zienkiewicz Centre for Computational Engineering has an extensive track record of industrial collaboration and contributes to many exciting projects, including the aerodynamics for the current World Land Speed Record car, Thrust SSC, and the future BLOODHOUND SSC, and the design of the double-decker super-jet Airbus A380.

Careers

Employment in a wide range of industries, which require the skills developed during the Computer Modelling and Finite Elements in Engineering Mechanics course, from aerospace to the medical sector. Computational modelling techniques have developed in importance to provide solutions to complex problems and as a graduate of this course in Computer Modelling and Finite Elements in Engineering Mechanics, you will be able to utilise your highly sought-after skills in industry or research.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

The REF assesses the quality of research in the UK Higher Education sector, assuring us of the standards we strive for.

World-Leading Research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.



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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Erasmus Mundus Computational Mechanics at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Erasmus Mundus Computational Mechanics at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

Swansea University has gained a significant international profile as one of the key international centres for research and training in computational mechanics and engineering. As a student on the Master's course in Erasmus Mundus Computational Mechanics, you will be provided with in-depth, multidisciplinary training in the application of the finite element method and related state-of-the-art numerical and computational techniques to the solution and simulation of highly challenging problems in engineering analysis and design.

Key Features of Erasmus Mundus Computational Mechanics MSc

The Zienkiewicz Centre for Computational Engineering is acknowledged internationally as the leading UK centre for computational engineering research. It represents an interdisciplinary group of researchers who are active in computational or applied mechanics. It is unrivalled concentration of knowledge and expertise in this field. Many numerical techniques currently in use in commercial simulation software have originated from Swansea University.

The Erasmus Mundus MSc Computational Mechanics course is a two-year postgraduate programme run by an international consortium of four leading European Universities, namely Swansea University, Universitat Politècnica de Catalunya (Spain), École Centrale de Nantes (France) and University of Stuttgart (Germany) in cooperation with the International Centre for Numerical Methods in Engineering (CIMNE, Spain).

As a student on the Erasmus Mundus MSc Computational Mechanics course, you will gain a general knowledge of the theory of computational mechanics, including the strengths and weaknesses of the approach, appreciate the worth of undertaking a computational simulation in an industrial context, and be provided with training in the development of new software for the improved simulation of current engineering problems.

In the first year of the Erasmus Mundus MSc Computational Mechanics course, you will follow an agreed common set of core modules leading to common examinations in Swansea or Barcelona. In addition, an industrial placement will take place during this year, where you will have the opportunity to be exposed to the use of computational mechanics within an industrial context. For the second year of the Erasmus Mundus MSc Computational Mechanics, you will move to one of the other Universities, depending upon your preferred specialisation, to complete a series of taught modules and the research thesis. There will be a wide choice of specialisation areas (i.e. fluids, structures, aerospace, biomedical) by incorporating modules from the four Universities. This allows you to experience postgraduate education in more than one European institution.

Modules

Modules on the Erasmus Mundus MSc Computational Mechanics course can vary each year but you could expect to study the following core modules (together with elective modules):

Numerical Methods for Partial Differential Equations

Continuum Mechanics

Advanced Fluid Mechanics

Industrial Project

Finite Element Computational Analysis

Entrepreneurship for Engineers

Finite Element in Fluids

Computational Plasticity

Fluid-Structure Interaction

Nonlinear Continuum Mechanics

Computational Fluid Dynamics

Dynamics and Transient Analysis

Reservoir Modelling and Simulation

Accreditation

The Erasmus Mundus Computational Mechanics course is accredited by the Joint Board of Moderators (JBM).

The Joint Board of Moderators (JBM) is composed of the Institution of Civil Engineers (ICE), the Institution of Structural Engineers (IStructE), the Chartered Institution of Highways and Transportation (CIHT), and the Institute of Highway Engineers (IHE).

This degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

See http://www.jbm.org.uk for further information.

This degree has been accredited by the JBM under licence from the UK regulator, the Engineering Council.

Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). An accredited degree will provide you with some or all of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng). Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.

Links with Industry

On the Erasmus Mundus MSc Computational Mechanics course, you will have the opportunity to apply your skills and knowledge in computational mechanics in an industrial context.

As a student on the Erasmus Mundus MSc Computational Mechanics course you will be placed in engineering industries, consultancies or research institutions that have an interest and expertise in computational mechanics. Typically, you will be trained by the relevant industry in the use of their in-house or commercial computational mechanics software.

You will also gain knowledge and expertise on the use of the particular range of commercial software used in the industry where you are placed.

Careers

The next decade will experience an explosive growth in the demand for accurate and reliable numerical simulation and optimisation of engineering systems.

Computational mechanics will become even more multidisciplinary than in the past and many technological tools will be, for instance, integrated to explore biological systems and submicron devices. This will have a major impact in our everyday lives.

Employment can be found in a broad range of engineering industries as this course provides the skills for the modelling, formulation, analysis and implementation of simulation tools for advanced engineering problems.

Student Quotes

“I gained immensely from the high quality coursework, extensive research support, confluence of cultures and unforgettable friendship.”

Prabhu Muthuganeisan, MSc Computational Mechanics



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Innovative design allows more interesting and functional architecture but challenges traditional concepts of fire safety. To respond to these demands takes specialist knowledge and advanced skills in engineering analysis. Read more

Innovative design allows more interesting and functional architecture but challenges traditional concepts of fire safety. To respond to these demands takes specialist knowledge and advanced skills in engineering analysis.

This programme covers the fundamentals of fire science, including laboratory classes, fire safety engineering and relevant structural engineering topics, such as finite element methods.

You will gain knowledge of the critical issues in structural fire safety engineering, and an understanding of relevant fire and structural behaviours.

You will become familiar with performance-based approaches to design and have an awareness of the capabilities – and limitations – of relevant advanced modelling methods for structures and fire.

This programme is fully accredited by the Joint Board of Moderators (JBM)

Facilities

Our Building Research Establishment (BRE) Centre for Fire Safety Engineering hosts bespoke equipment to support groundbreaking research and teaching, with combined thermal and mechanical loading and use of the latest image analysis techniques.

Programme structure

This programme is run over 12 months, with two semesters of taught courses followed by a research project leading to a masters thesis.

Semester 1 courses

  • Fire Science and Fire Dynamics
  • State-of-the-Art Review in Fire Safety Engineering
  • Structural Design for Fire
  • Finite Element Analysis for Solids
  • Thin-Walled Members and Stability

Plus one of:

  • Fire Investigation and Failure Analysis
  • Fire Safety, Engineering & Society

Semester 2 courses

  • Pre-Dissertation Project in Fire Safety Engineering
  • Fire Science Laboratory
  • Fire Safety Engineering Analysis and Design
  • The Finite Element Method
  • Structural Dynamics and Earthquake Engineering

Career opportunities

Internationally, there is great demand for graduates in this field, with expertise in structural fire safety engineering particularly sought after as performance-based design expands. All of our previous graduates are in relevant employment, with the majority working in fire teams at engineering consultancies.



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Mechanical engineers are both generalists and specialists, bringing broad expertise and specialised mastery to their roles as project managers, leaders and innovators. Read more

Mechanical engineers are both generalists and specialists, bringing broad expertise and specialised mastery to their roles as project managers, leaders and innovators. As a student of GCU's MSc Mechanical Engineering, you'll continue in this tradition. The programme is designed to expand your core knowledge of the discipline while enhancing your skills as a specialist in either design or manufacture.

The programme was developed according to the UK Engineering Council's benchmark requirements for professional engineering, ensuring you'll enter the workforce with the relevant capabilities that employers value. It is also accredited by the Institution of Mechanical Engineers (IMechE). Furthermore, our industrial advisory board offers strong connections to industry.

GCU's mechanical engineering department contributes to important research in the discipline, investigating topics like materials and manufacturing, finite element analysis, computer-aided design and manufacture, and machine condition monitoring.

The MSc Mechanical Engineering curriculum encourages you to develop as a professional as well as an engineer.

  • Build your interpersonal skills to succeed as a team member and manager
  • Explore topics such as project planning and methodology, strategy and innovation, and computer-aided engineering
  • Practise managing resources and meeting project objectives
  • Choose from two options for specialisation: Design or Manufacture

When you study engineering at GCU, you'll join a welcoming community of learners and professionals. You'll find classmates and colleagues who are creative and entrepreneurial, committed to using their expertise to make a positive impact and advance the common good.

What you will study

The programme offers two specialist study options; Design and Manufacture. These options share a number of common modules that directly reflect the activities of a professional mechanical engineer. Students complete eight taught modules - four in trimester A and four in trimester B; and an MSc dissertation in trimester C.

  • Project Planning and Methodology
  • Strategy and Innovation
  • Advanced Computer-Aided Engineering
  • Condition Monitoring
  • Project
  • Specialist Modules (Design)
  • Specialist Modules (Manufacture)

Assessment methods

The taught modules are either assessed by coursework only or a combination of coursework and examination. In the later case the final mark is determined by weighted average of the two elements. The MSc project is assessed by project reports, practical operation and an electronic presentation.

Professional accreditation

The development of these Masters options is in direct response to the specification of benchmark requirements for professional competence by the UK's Engineering Council (UK-SPEC). This programme is accredited by the Institution of Mechanical Engineers (IMechE).

Why choose this programme?

The MSc in Mechanical Engineering has very strong industrial links through its industry advisory board. The school participates in many research activities within the area of mechanical engineering. This includes; advanced materials and manufacturing processes, finite element analysts, computer-aided design and manufacture and machine condition monitoring.

HM Forces

In partnership with HM Forces, GCU has identified this programme is being particularly suited to military and ex-military men and women. Visit the HM Forces Careers Zone for more information on the services we provide.

Graduate prospects

Our graduates are appreciated by employers for their career-focused attitudes and socially driven perspectives. With skilled engineers in high demand, you can expect excellent job prospects in the field.

Graduates of the MSc Mechanical Engineering find employment in the oil and gas industry, defence, computer-aided engineering and building. They also work in mechanical design engineering, project engineering, manufacturing engineering and engineering sales.



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Modern industry operates within a highly competitive global market, the adoption, exploration and management of technology across both design and manufacture and product simulation performance is at the forefront of providing successful business with the competitive edge needed to survive and grow. Read more

Modern industry operates within a highly competitive global market, the adoption, exploration and management of technology across both design and manufacture and product simulation performance is at the forefront of providing successful business with the competitive edge needed to survive and grow. In addition, society is demanding that such business enterprises become evermore proactive in terms of adopting a more socially conscious approach, such as sustainability, across all their strategies and operations.

This course aims to develop your knowledge and understanding of modern engineering analysis and simulation tools and techniques in terms of product development and optimisation before manufacture. You will gain a comprehensive understanding of how various IT-based tools and systems function while also gaining insights into how these are implemented effectively, within the manufacturing and industrial sectors. You will be equipped to undertake cross-functional management roles and to evaluate how modern organisations can strategically exploit existing and emerging technologies. This reflects the growing demand for specialists with advanced skills and knowledge to drive forward effective, new, product development and their introduction across all of the major industrial sectors including automotive, aerospace and general manufacture.

The course will allow you acquire advanced knowledge and systematic understanding of contemporary finite element modelling techniques to analyse the behaviour of complex engineering systems and components. It will involve a comprehensive understanding of advanced solid mechanics and analytical techniques pertinent to product development and sustainability, and to apply these advanced techniques to synthesise novel designs of a range of engineering systems.

What happens on the course?

  • Research Methods and Professional Skills
  • Project Management Tools and Techniques
  • CAD and Product Definition
  • Emerging Design Tools
  • Dissertation
  • Simulation and Design Optimisation
  • Applied Stress Analysis

Why Wolverhampton?

This course provides you with the unique opportunity to experience the practicalities and applications of modern Engineering Analysis Techniques. The dedicated IT simulation resources and expertise of our specialised staff, based at our Telford Campus, is well renowned and often called upon to support and advise external agencies and key industries across the aerospace, automotive and automotive sports and power generation sectors. You can therefore rest assured of access to a variety of significant simulation techniques facilities and expertise. Beyond this, the course will encourage and guide you to explore and conduct research into emerging Design and use the latest industry standard simulation software to produce complex, economical and sustainable part/component part production. Our expectation is that the exposure offered by the course, to modern and newly emerging manufacturing technologies coupled with the project managerial aspects of the course will ensure that you are well placed to take up a key role in this dynamic industrial sector.

You will have the opportunity to engage with a range of learning approaches during the course of your study.

You will take part in lectures and seminars. Some of these will be more traditional whereas others will require you to undertake research before coming together to discuss technical issues with a range of students and academic staff. You will have seminars from industry practitioners and have the opportunity to discuss your projects with them to gain real world insight into the problems you are trying to solve.

You will have the opportunity to work in a range of dedicated facilities such as the Dedicated IT Laboratories to develop practical skills and understand the link between the theory and practical implementation of integrated CAD, Simulation and Finite Element Analysis Techniques. Throughout the weekly class sessions and through use of the on-line support material, you will obtain skills required to successfully implement and manage a range of modern design and simulation systems, processes and methodologies.

Often working on assessment and project briefs specified by industry practitioners, you will develop solutions to meet real world problems/requirements and be able to present these to your peers, practitioners and third parties in order to obtain balanced and current feedback.

Career path

The course is aimed at Science and Technology graduates who aspire to Engineering and Manufacturing management roles, in leading industrial organisations.

On completion of the programme, you can expect to develop your career leading to senior management where strategic thinking skills, project management experience and a deeper technological knowledge-base would be beneficial.

What skills will you gain?

  • Develop novel strategies for the management and deployment of advanced and emerging technologies, tools and techniques.
  • Select and apply appropriate industry standard computer aided engineering software and analysis methods to model, analyse and evaluate engineering systems and solve engineering problems.
  • Apply knowledge to create original concepts for products, engineering systems or processes.
  • Make use of high level skills and abilities to exploit generic and bespoke software tools, solve complex design, configuration or process problems and thereby develop industrially appropriate solutions for delivery to a range of audiences.
  • Be fully conversant with the theories underpinning the fundamental principles that govern Stress Analysis
  • Model and analytically analyse the behaviour of structures and engineering components under complex loading conditions especially in specific applications such as those encountered in the automotive, aeronautical, aerospace and power generation industries


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This MSc programme offers very relevant modules in highly sought-after engineering and scientific subjects. Read more
This MSc programme offers very relevant modules in highly sought-after engineering and scientific subjects. Computational modelling has become an essential part of industrial product development; the manufacturing sector in particular has been experiencing a significant uptake of computational engineering technologies to increase its competitiveness in the global market. This programme is designed for engineering and science graduates, providing a wide exploration of these new and advanced technologies. Problem based learning facilities the application of the modelling techniques.

Subject guide and modules

The range of modules reflects the nature of engineering modelling and the uses it is put to in engineering and commercial practice.
Core modules:
-Computational Fluid Dynamics and Applications (ME4501)
-Practical Numerical Methods (ME4510)
-CAD Principles and Materials Selection (ME4505)
-Advanced Computer Aided Design (ADVCAD) (ME4518)
-Major Project (PD4000)
-Research Project (PD4001)
-Renewable Energy (ME4504)
-Sustainable Design (PD4005)

Elective Modules:
-Solid Mechanics and Finite Element Analysis (ME3070)
-Strategic Finance (EM4001)
-Project Management (EM4003)
-New Product Development (EM4006)
-Innovation Business Development (PD4008)
-Finite Element Analysis: Theory and Application (ME4502)

Learning, teaching & assessment

The modules in this programme are delivered with lectures and lab-based tutorials giving a good balance between scientific methodologies and hands-on practice.

There is a heavy emphasis on the use of computational engineering methods and this is reflected in the way the programme is delivered and assessed.

Modules are assessed through either course work or exams. The major project is assessed by dissertation; examples of past major projects include development of CFD code, aero and structural dynamics of vehicles and aircraft, and analysis of development of industrial machines.

Personal development

Along with the range of technical skills, the Programme aims to develop self reliance, project management, IT communications and research skills.

You will develop and deliver a major dissertation and the necessary project management processes. You will also make several individual presentations and get chance to hone your interview techniques.

Career prospects

Career prospects for graduates are excellent. The programme puts practical engineering modelling, research and project management skills in to the hands of graduate. This helps career progression in industries where computer-based technology is required including manufacturing, R&D, science, IT, design and academia.

Recent graduates have been employed in a range of jobs including:
-Product development with a manufacturer of domestic heating products
-Computer aided design with a manufacturer of military/surveillance equipment

Professional accreditation

The MSc Mechanical Engineering (Modelling) is accredited by the Institution of Mechanical Engineers (IMechE) for the purpose of meeting the educational requirements of Chartered Engineer (CEng).

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This programme will equip you with the knowledge and skills you need to meet the needs of the automotive industry in the advanced areas of analysis, design and manufacture. Read more

This programme will equip you with the knowledge and skills you need to meet the needs of the automotive industry in the advanced areas of analysis, design and manufacture.

Traditionally, the sector has been associated with high-volume vehicle manufacture, but the past decade has seen the landscape shift towards automotive component manufacturers and specialist design and consultancy house.

This course will prepare you to work in a range of different settings. Core modules will develop your knowledge of key fields such as chassis and driveline engineering, as well as vehicle and product systems design. You’ll then choose from optional modules on topics that suit your own interests and career intentions.

We put particular emphasis on computational methods and software packages in automotive engineering analysis, design and manufacture. Depending on the modules you choose, you could use Matlab, Abaqus finite element code, Fluent CFD, SolidWorks CAE and LabView (DAQ and control).

Specialist facilities

You’ll benefit from working in world-class specialist facilities for different aspects of automotive engineering. These include a brake test area and measurement lab, as well as the latest industry-standard software for computational fluid dynamics and finite element modelling of systems and materials. ADAMS software is also available for suspension simulation.

High-level CNC and wire EDM facilities are available in the Faculty workshop, and we have cutting-edge tribology facilities to study wear on engine parts. There’s even a ‘stirred bomb’ for characterising fuel ignition and advanced engines with optical access. If you get involved with Formula Student race car, you’ll also use our dedicated car build area including computerised engine test bays.

This programme is also available to study part-time over 24 months.

Accreditation

This course is accredited by the Institute of Mechanical Engineers (IMechE) under licence from the UK regulator, the Engineering Council.



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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Computer Modelling in Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Computer Modelling in Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

This MRes in Computer Modelling in Engineering programme consists of two streams: students may choose to specialise in either structures or fluids. The taught modules provide a good grounding in computer modelling and in the finite element method, in particular.

Key Features of MRes in Computer Modelling in Engineering

Computer simulation is now an established discipline that has an important role to play in engineering, science and in newly emerging areas of interdisciplinary research.

Using mathematical modelling as the basis, computational methods provide procedures which, with the aid of the computer, allow complex problems to be solved. The techniques play an ever-increasing role in industry and there is further emphasis to apply the methodology to other important areas such as medicine and the life sciences.

The Zienkiewicz Centre for Computational Engineering, within which this course is run, has excellent computing facilities, including a state-of-the-art multi-processor super computer with virtual reality facilities and high-speed networking.

This Computer Modelling in Engineering course is suitable for those who are interested in gaining a solid understanding of computer modelling, specialising in either structures or fluids, and taking the skills gained through this course to develop their career in industry or research.

If you would like to qualify as a Chartered Engineer, this course is accredited with providing the additional educational components for the further learning needed to qualify as a Chartered Engineer, as set out by UK and European engineering professional institutions.

Modules

Modules on the Computer Modelling in Engineering programme typically include:

• Finite Element and Computational Analysis

• Numerical Methods for Partial Differential Equations

• Solid Mechanics

• Advanced Fluid Mechanics

• Dynamics and Transient Analysis

• Communication Skills for Research Engineers

• MRes Research Project

Accreditation

The MRes Computer Modelling in Engineering course is accredited by the Joint Board of Moderators (JBM).

The Joint Board of Moderators (JBM) is composed of the Institution of Civil Engineers (ICE), the Institution of Structural Engineers (IStructE), the Chartered Institution of Highways and Transportation (CIHT), and the Institute of Highway Engineers (IHE).

The MRes Computer Modelling in Engineering degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

The MRes Computer Modelling in Engineering degree has been accredited by the JBM under licence from the UK regulator, the Engineering Council.

Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). An accredited degree will provide you with some or all of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng). Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.

Links with Industry

The Civil and Computational Engineering Centre has an extensive track record of industrial collaboration and contributes to many exciting projects, including the aerodynamics for the current World Land Speed Record car, Thrust SSC, and the future BLOODHOUND SSC, and the design of the double-decker super-jet Airbus A380.

Examples of recent collaborators and sponsoring agencies include: ABB, Audi, BAE Systems, British Gas, Cinpress, DERA, Dti, EADS, EPSRC, European Union, HEFCW, HSE, Hyder, Mobil, NASA, Quinshield, Rolls-Royce, South West Water, Sumitomo Shell, Unilever, US Army, WDA.

Student Quotes

“I was attracted to the MRes course at Swansea as the subject matter was just what I was looking for.

I previously worked as a Cardiovascular Research Assistant at the Murdoch Children’s Research Institute in Melbourne. My employer, the Head of the Cardiology Department, encouraged me to develop skills in modelling as this has a lot of potential to help answer some current questions and controversies in the field. I was looking for a Master’s level course that could provide me with computational modelling skills that I could apply to blood flow problems, particularly those arising from congenital heart disease.

The College of Engineering at Swansea is certainly a good choice. In the computational modelling area, it is one of the leading centres in the world (they wrote the textbook, literally). A lot of people I knew in Swansea initially came to study for a couple of years, but then ended up never leaving. I can see how that could happen.”

Jonathan Mynard, MRes Computer Modelling in Engineering, then PhD at the University of Melbourne, currently post-doctoral fellow at the Biomedical Simulation Laboratory, University of Toronto, Canada

Careers

Employment in a wide range of industries, which require the skills developed during the Computer Modelling in Engineering course, from aerospace to the medical sector. Computational modelling techniques have developed in importance to provide solutions to complex problems and as a graduate of this course, you will be able to utilise your highly sought-after skills in industry or research.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

World-leading research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.

Highlights of the Engineering results according to the General Engineering Unit of Assessment:

Research Environment at Swansea ranked 2nd in the UK

Research Impact ranked 10th in the UK

Research Power (3*/4* Equivalent staff) ranked 10th in the UK



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This MSc programme provides its students with an opportunity to extend the technical knowledge acquired on an undergraduate degree programme in mechanical or manufacturing engineering. Read more

This MSc programme provides its students with an opportunity to extend the technical knowledge acquired on an undergraduate degree programme in mechanical or manufacturing engineering.

Though not a specialist Master's degree, the programme provides a broad subject-specific curriculum that provides an opportunity for students to tailor the programme to meet their personal needs, with specialism pursued through a major project.

Research project

Many of these projects reflect the key research interests of the department, such as manufacturing, bulk materials handling and instrumentation. However, projects can be selected from across the discipline from a list provided by the department. Many projects are derived from our industrial links, and a number are proposed by students, reflecting their personal interests or experience.

Accreditation

This programme is accredited by the Institution of Engineering and Technology as fully satisfying the further learning requirements for chartered engineer (CEng) registration. An individual holding an accredited MSc must also hold a CEng-accredited honours degree to have the full exemplifying qualifications for CEng status.

Outcomes

The aims of the programme are to:

  • Provide students with an enhanced base of knowledge and current and reflective practice necessary to initiate a career in mechanical and manufacturing engineering at the professional engineer level
  • Enhance specialist knowledge in the area of mechanical and manufacturing engineering which build upon studies at the undergraduate level
  • Further develop improved skills of independent learning and critical appraisal
  • Develop an extensive insight into industrial applications and requirements
  • Develop critical insight of management issues relating to engineering business.

Full time

Year 1

Students are required to study the following compulsory courses.

Part time

Year 1

Students are required to study the following compulsory courses.

Year 2

Students are required to study the following compulsory courses.

Assessment

Students are assessed through examinations, case studies, assignments, practical work and a dissertation.

Careers

This programme provides a wide variety of opportunities for mechanical and manufacturing engineers in a range of sectors, from the automotive to the process industries.



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To gain this qualification, you need 180 credits as follows. Stage 1. 60 credits from List A. List A. optional modules. Advanced routing - CCNP 1 (T824). Read more

Modules

To gain this qualification, you need 180 credits as follows:

Stage 1

60 credits from List A:

List A: optional modules

• Advanced routing - CCNP 1 (T824)
• Capacities for managing development (T878)
• Conflict and development (T879)
• Development: context and practice (T877)
• Environmental monitoring and protection (T868)
• Finite element analysis: basic principles and applications (T804)
• Institutional development (TU872)
• Making environmental decisions (T891)
• Managing for sustainability (T867)
• Managing systemic change: inquiry, action and interaction (TU812)
• Managing technological innovation (T848)
• Manufacture materials design (T805)
• Multilayer switching - CCNP 3 (T826)
• Network security (T828)
• Optimising networks - CCNP 4 (T827)
• Problem solving and improvement: quality and other approaches (T889)
• Strategic capabilities for technological innovation (T849)
• Thinking strategically: systems tools for managing change (TU811)

Plus 30 credits from List B:

List B: optional modules

• Advanced mathematical methods (M833)
• Advanced routing - CCNP 1 (T824)
• Analytic number theory I (M823)
• Analytic number theory II (M829)
• Applied complex variables (M828)
• Approximation theory (M832)
• Calculus of variations and advanced calculus (M820)
• Capacities for managing development (T878)
• Coding theory (M836)
• Conflict and development (T879)
• Data management (M816)
• Developing research skills in science (S825)
• Development: context and practice (T877)
• Digital forensics (M812)
• Environmental monitoring and protection (T868)
• Finite element analysis: basic principles and applications (T804)
• Fractal geometry (M835)
• Information security (M811)
• Institutional development (TU872)
• Making environmental decisions (T891)
• Managing for sustainability (T867)
• Managing systemic change: inquiry, action and interaction (TU812)
• Managing technological innovation (T848)
• Manufacture materials design (T805)
• Multilayer switching - CCNP 3 (T826)
• Network security (T828)
• Nonlinear ordinary differential equations (M821)
• Optimising networks - CCNP 4 (T827)
• Problem solving and improvement: quality and other approaches (T889)
• Project management (M815)
• Researching mathematics learning (ME825)*
• Software development (M813)
• Software engineering (M814)
• Space science (S818) NEW1
• Strategic capabilities for technological innovation (T849)
• Thinking strategically: systems tools for managing change (TU811)

* 60-credit module of which only 30 credits count towards this qualification

Plus 30 credits from:

Compulsory module

Team engineering (T885)

Stage 2

60 credits from:

Compulsory module

Research project (T802)

The modules quoted in this description are currently available for study. However, as we review the curriculum on a regular basis, the exact selection may change over time.

Credit transfer

Credit transfer is not permitted for the MSc except for any awarded as part of the Postgraduate Diploma in Engineering.
For further advice and guidance, please email us.

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This MSc programme offers you an advanced level of study in specific aspects of mechanical engineering which are in demand from industry. Read more

This MSc programme offers you an advanced level of study in specific aspects of mechanical engineering which are in demand from industry. It is an ideal bridging programme for those graduates seeking to register as a Chartered Engineer with the Institution of Mechanical Engineers.

Course details

You study the core modules in CAD/CAM and Product Development, Finite Element Methods and Machine Design and you select three additional modules from Automotive Engineering and Vehicle Design, Manufacturing Systems, Project Management and Enterprise, Supply Chain Management and Applied Continuum Mechanics.

Professional accreditation

Our MSc Mechanical Engineering is accredited to CEng level by the Institution of Mechanical Engineers under licence from the UK regulator, the Engineering Council. Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). 

The accredited Masters-level award will provide you with the underpinning knowledge, understanding and skills in preparation for your registration as a Chartered Engineer (CEng). Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.

What you study

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

Course structure

Core modules

  • CAD/CAM and Product Developments
  • Finite Element Methods
  • Machine Design
  • Practical Health and Safety Skills
  • Project Management and Enterprise
  • Research and Study Skills

and three optional modules

  • Applied Continuum Mechanics
  • Automotive Engineering and Vehicle Design
  • Manufacturing Systems
  • Supply Chain Management

MSc candidates

  • Project

Modules offered may vary.

Teaching

How you learn

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

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

How you are assessed

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

Employability

Mechanical engineers typically secure employment in structural engineering, research and development, automotive engineering and design, the aerospace industry, manufacturing, processing and chemical industries as well as management positions.



Read less
This MSc programme offers you an advanced level of study in specific aspects of mechanical engineering which are in demand from industry. Read more

This MSc programme offers you an advanced level of study in specific aspects of mechanical engineering which are in demand from industry. You study develop knowledge and key skills in CAD/CAM and Product Development, Finite Element Methods and Machine Design and options available include Automotive Engineering and Vehicle Design, Manufacturing Systems, Project Management and Enterprise, Supply Chain Management and Applied Continuum Mechanics.

Course details

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

  • MSc Mechanical Engineering – one year full time
  • MSc Mechanical Engineering – two years part time
  • MSc Mechanical Engineering (with Advanced Practice) – two years full time

The one-year programme is a great option if you want to gain a traditional MSc qualification – you can find out more here. This two-year master’s degree with advanced practice enhances your qualification by adding to the one-year master’s programme an internship, research or study abroad experience.

Professional accreditation

Our one-year MSc Mechanical Engineering is accredited to CEng level by the Institution of Mechanical Engineers under licence from the UK regulator, the Engineering Council. Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). [include Engineering Council logo, Institution of Mechanical Engineers logo]

The accredited Masters-level award will provide you with the underpinning knowledge, understanding and skills in preparation for your registration as a Chartered Engineer (CEng). Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.

The two-year MSc Mechanical Engineering with Advanced Practice incorporates all the elements of the one-year MSc and adds to these the advanced practice module. The new title is being prepared for formal recognition as accredited title. 

What you study

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

Course structure

Core modules

  • CAD/CAM and Product Developments
  • Finite Element Methods
  • Machine Design
  • Practical Health and Safety Skills
  • Project Management and Enterprise
  • Research and Study Skills
  • Research Project (Advanced Practice)

and two optional modules

  • Applied Continuum Mechanics
  • Automotive Engineering and Vehicle Design
  • Manufacturing Systems
  • Supply Chain Management

Advanced Practice options

  • Research Internship
  • Study Abroad
  • Vocational Internship

Modules offered may vary.

Teaching

How you learn

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

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

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

How you are assessed

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

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

Employability

Mechanical engineers typically work in structural engineering, research and development, automotive engineering and design, the aerospace industry, manufacturing, processing and chemical industries as well as management positions.



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Modern industry operates within a highly competitive global market, the adoption, exploration and management of technology across both design and manufacture and product simulation performance is at the forefront of providing successful business with the competitive edge needed to survive and grow. Read more

Modern industry operates within a highly competitive global market, the adoption, exploration and management of technology across both design and manufacture and product simulation performance is at the forefront of providing successful business with the competitive edge needed to survive and grow. In addition, society is demanding that such business enterprises become evermore proactive in terms of adopting a more socially conscious approach, such as sustainability, across all their strategies and operations.

This course aims to develop your knowledge and understanding of modern engineering analysis and simulation tools and techniques in terms of product development and optimisation before manufacture. You will gain a comprehensive understanding of how various IT-based tools and systems function while also gaining insights into how these are implemented effectively, within the manufacturing and industrial sectors. You will be equipped to undertake cross-functional management roles and to evaluate how modern organisations can strategically exploit existing and emerging technologies. This reflects the growing demand for specialists with advanced skills and knowledge to drive forward effective, new, product development and their introduction across all of the major industrial sectors including automotive, aerospace and general manufacture.

The course will allow you acquire advanced knowledge and systematic understanding of contemporary finite element modelling techniques to analyse the behaviour of complex engineering systems and components. It will involve a comprehensive understanding of advanced solid mechanics and analytical techniques pertinent to product development and sustainability, and to apply these advanced techniques to synthesise novel designs of a range of engineering systems.

What happens on the course?

  • Research Methods and Professional Skills
  • Project Management Tools and Techniques
  • CAD and Product Definition
  • Emerging Design Tools
  • Dissertation
  • Simulation and Design Optimisation
  • Applied Stress Analysis

Why Wolverhampton?

This course provides you with the unique opportunity to experience the practicalities and applications of modern Engineering Analysis Techniques. The dedicated IT simulation resources and expertise of our specialised staff, based at our Telford Campus, is well renowned and often called upon to support and advise external agencies and key industries across the aerospace, automotive and automotive sports and power generation sectors. You can therefore rest assured of access to a variety of significant simulation techniques facilities and expertise. Beyond this, the course will encourage and guide you to explore and conduct research into emerging Design and use the latest industry standard simulation software to produce complex, economical and sustainable part/component part production. Our expectation is that the exposure offered by the course, to modern and newly emerging manufacturing technologies coupled with the project managerial aspects of the course will ensure that you are well placed to take up a key role in this dynamic industrial sector.

You will have the opportunity to engage with a range of learning approaches during the course of your study.

You will take part in lectures and seminars. Some of these will be more traditional whereas others will require you to undertake research before coming together to discuss technical issues with a range of students and academic staff. You will have seminars from industry practitioners and have the opportunity to discuss your projects with them to gain real world insight into the problems you are trying to solve.

You will have the opportunity to work in a range of dedicated facilities such as the Dedicated IT Laboratories to develop practical skills and understand the link between the theory and practical implementation of integrated CAD, Simulation and Finite Element Analysis Techniques. Throughout the weekly class sessions and through use of the on-line support material, you will obtain skills required to successfully implement and manage a range of modern design and simulation systems, processes and methodologies.

Often working on assessment and project briefs specified by industry practitioners, you will develop solutions to meet real world problems/requirements and be able to present these to your peers, practitioners and third parties in order to obtain balanced and current feedback.

Career path

The course is aimed at Science and Technology graduates who aspire to Engineering and Manufacturing management roles, in leading industrial organisations.

On completion of the programme, you can expect to develop your career leading to senior management where strategic thinking skills, project management experience and a deeper technological knowledge-base would be beneficial.

What skills will you gain?

  • Develop novel strategies for the management and deployment of advanced and emerging technologies, tools and techniques.
  • Select and apply appropriate industry standard computer aided engineering software and analysis methods to model, analyse and evaluate engineering systems and solve engineering problems.
  • Apply knowledge to create original concepts for products, engineering systems or processes.
  • Make use of high level skills and abilities to exploit generic and bespoke software tools, solve complex design, configuration or process problems and thereby develop industrially appropriate solutions for delivery to a range of audiences.
  • Be fully conversant with the theories underpinning the fundamental principles that govern Stress Analysis
  • Model and analytically analyse the behaviour of structures and engineering components under complex loading conditions especially in specific applications such as those encountered in the automotive, aeronautical, aerospace and power generation industries


Read less
Modern industry operates within a highly competitive global market, the adoption, exploration and management of technology across both design and manufacture and product simulation performance is at the forefront of providing successful business with the competitive edge needed to survive and grow. Read more

Modern industry operates within a highly competitive global market, the adoption, exploration and management of technology across both design and manufacture and product simulation performance is at the forefront of providing successful business with the competitive edge needed to survive and grow. In addition, society is demanding that such business enterprises become evermore proactive in terms of adopting a more socially conscious approach, such as sustainability, across all their strategies and operations.

This course aims to develop your knowledge and understanding of modern engineering analysis and simulation tools and techniques in terms of product development and optimisation before manufacture. You will gain a comprehensive understanding of how various IT-based tools and systems function while also gaining insights into how these are implemented effectively, within the manufacturing and industrial sectors. You will be equipped to undertake cross-functional management roles and to evaluate how modern organisations can strategically exploit existing and emerging technologies. This reflects the growing demand for specialists with advanced skills and knowledge to drive forward effective, new, product development and their introduction across all of the major industrial sectors including automotive, aerospace and general manufacture.

The course will allow you acquire advanced knowledge and systematic understanding of contemporary finite element modelling techniques to analyse the behaviour of complex engineering systems and components. It will involve a comprehensive understanding of advanced solid mechanics and analytical techniques pertinent to product development and sustainability, and to apply these advanced techniques to synthesise novel designs of a range of engineering systems.

What happens on the course?

  • Research Methods and Professional Skills
  • Project Management Tools and Techniques
  • CAD and Product Definition
  • Emerging Design Tools
  • Dissertation
  • Simulation and Design Optimisation
  • Applied Stress Analysis

Why Wolverhampton?

This course provides you with the unique opportunity to experience the practicalities and applications of modern Engineering Analysis Techniques. The dedicated IT simulation resources and expertise of our specialised staff, based at our Telford Campus, is well renowned and often called upon to support and advise external agencies and key industries across the aerospace, automotive and automotive sports and power generation sectors. You can therefore rest assured of access to a variety of significant simulation techniques facilities and expertise. Beyond this, the course will encourage and guide you to explore and conduct research into emerging Design and use the latest industry standard simulation software to produce complex, economical and sustainable part/component part production. Our expectation is that the exposure offered by the course, to modern and newly emerging manufacturing technologies coupled with the project managerial aspects of the course will ensure that you are well placed to take up a key role in this dynamic industrial sector.

You will have the opportunity to engage with a range of learning approaches during the course of your study.

You will take part in lectures and seminars. Some of these will be more traditional whereas others will require you to undertake research before coming together to discuss technical issues with a range of students and academic staff. You will have seminars from industry practitioners and have the opportunity to discuss your projects with them to gain real world insight into the problems you are trying to solve.

You will have the opportunity to work in a range of dedicated facilities such as the Dedicated IT Laboratories to develop practical skills and understand the link between the theory and practical implementation of integrated CAD, Simulation and Finite Element Analysis Techniques. Throughout the weekly class sessions and through use of the on-line support material, you will obtain skills required to successfully implement and manage a range of modern design and simulation systems, processes and methodologies.

Often working on assessment and project briefs specified by industry practitioners, you will develop solutions to meet real world problems/requirements and be able to present these to your peers, practitioners and third parties in order to obtain balanced and current feedback.

Career path

The course is aimed at Science and Technology graduates who aspire to Engineering and Manufacturing management roles, in leading industrial organisations.

On completion of the programme, you can expect to develop your career leading to senior management where strategic thinking skills, project management experience and a deeper technological knowledge-base would be beneficial.

What skills will you gain?

  • Develop novel strategies for the management and deployment of advanced and emerging technologies, tools and techniques.
  • Select and apply appropriate industry standard computer aided engineering software and analysis methods to model, analyse and evaluate engineering systems and solve engineering problems.
  • Apply knowledge to create original concepts for products, engineering systems or processes.
  • Make use of high level skills and abilities to exploit generic and bespoke software tools, solve complex design, configuration or process problems and thereby develop industrially appropriate solutions for delivery to a range of audiences.
  • Be fully conversant with the theories underpinning the fundamental principles that govern Stress Analysis
  • Model and analytically analyse the behaviour of structures and engineering components under complex loading conditions especially in specific applications such as those encountered in the automotive, aeronautical, aerospace and power generation industries


Read less
This programme has been designed to meet the challenges of the rapidly changing global market by providing the skills and abilities to contribute to the availability of well-designed products, process and systems. Read more
This programme has been designed to meet the challenges of the rapidly changing global market by providing the skills and abilities to contribute to the availability of well-designed products, process and systems.

As a broad-based Mechanical Engineering degree this programme provides a wide variety of career options in the engineering sector.

Core study areas include experimental mechanics, simulation of advanced materials and processes structural analysis, computer aided engineering, engineering design methods, sustainable development: the engineering context, the innovation process and project management, thermofluids and a project.

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

Programme modules

- Experimental Mechanics
This module introduces the following elements: experimental techniques for analysis and characterisation of various engineering materials and full-field, non-contact optical methods for deformation and strain measurements. Students will learn to identify the most appropriate experimental techniques for evaluating material response in a specific setting and for different types of materials.

- Simulation of Advanced Materials and Processes
The objective of this module is to introduce students to the concepts in numerical simulation of advanced materials and processes. To enable students to gain theoretical and practical experience in simulating mechanical behaviour of advanced materials and modelling processes related to these materials using finite element modelling techniques.

- Structural Analysis
Students will gain an understanding of modern concepts of structural analysis. They will gain practical experience in analyses of structures using finite-element modelling and understand the need for structural analysis in design.

- Computer Aided Engineering
Students will learn how to evaluate, choose and implement CAE systems. Students will learn to select and apply appropriate computer based methods and systems for modelling engineering products; analysing engineering problems; and assisting in the product design process.

- Engineering Design Methods
The aims of this module are to provide students with a working understanding of some of the main methods which may be employed in the design of products and systems. Students will learn to identify appropriate methods and techniques for use at different times and situations within a project.

- Sustainable Development: The Engineering Context
The objective of this module are to provide students with an understanding of the principles and practices of sustainable development and to provide them with an understanding of how engineers can help manufacturing businesses develop into more sustainable enterprises.

- The Innovation Process and Project Management
This module allows students to gain a clear overview of the innovation process and an understanding of the essential elements within it. Students will learn strategies for planning and carrying out innovative projects in any field.

- Thermofluids
In this module students study the fundamentals of combustion processes and understand key aspects relating to performance and emissions. Students develop knowledge and skills required by engineers entering industries involved in the design and use of combustion equipment.

- Project
In addition to the taught modules, all students undertake an individual major project. Part-time students normally undertake a major project that is based on the needs of their employing company.

How you will learn

You will learn through a carefully balanced combination of lectures, in-class guided workshops, hands-on computer modelling and independent research.

The programme consists of eight, week-long, taught lecture modules plus project work. Each taught module is self-contained and covers a complete target. This programme is available in both full-time and part-time forms. Full-time students commence their studies on the first Monday in October for a period of 12 months. Part-time students may commence their registration at any time between October and the following March, and take 3 years (typical) to complete the programme.

On completion of this programme, students should be able to:
- Plan and monitor multi-disciplinary projects;
- appreciate the central role of design within engineering;
- demonstrate competence in using computer based engineering techniques;
- analyse and understand complex engineering problems; and
- use team working skills and communicate effectively at an advanced technical level.

Facilities

As a student within the School of Mechanical and Manufacturing Engineering you will have access to a range of state-of-the-art equipment. Our computer labs are open 24/7 and use some of the latest industry standard software including STAR-CCM and CAD.

We have high-tech laboratories devoted to:
- Dynamics and control
- Electronics
- Fluid mechanics
- Materials
- Mechatronics
- Metrology
- Optical engineering
- Structural integrity
- Thermodynamics

Careers and further study

The programme will allow students to acquire the technical and transferable skills required to succeed in a career in industry or academic research. Graduates may also study for an MPhil or PhD with the School.

Scholarships

The University offers over 100 scholarships each year to new self-financing full-time international students who are permanently resident in a country outside the European Union. These scholarships are to the value of 25% of the programme tuition fee and that value will be credited to the student’s tuition fee account.
You can apply for a scholarship once you have received an offer for a place on this programme.

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/mechanical-engineering/

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