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Masters Degrees (Computer Aided)

We have 129 Masters Degrees (Computer Aided)

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The aim of this course is to develop students with high level knowledge and understanding of advanced Computer Aided Design (CAD) tools and techniques. Read more
The aim of this course is to develop students with high level knowledge and understanding of advanced Computer Aided Design (CAD) tools and techniques. Students will not only develop a comprehension of how the tools operate, but also how these can be implemented within the business context of the Architecture and Construction sectors.

Computer Aided Design and advanced visualisation techniques are at the forefront of the developments in the construction industry. Previous Government reports have highlighted that 18% of construction waste could be avoided by better production and of information drawings and use of integrated CAD data could assist in reducing this deficit.

The postgraduate programme in Computer Aided Design for Construction reflects the growing need to specialists with advanced CAD and visualisation skills to work in integrated construction teams. The programme provides you with a thorough understanding and practical skills in these exciting areas, including Building Information Modelling (BIM), architectural visualisation including photorealistic walkthroughs, real time visualisation, geographical information systems and how to implement and manage CAD systems.

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Computer Aided Engineering (CAE) covers the use of computers in all activities from the design to the manufacture of a product. It is at the forefront of information technology and of crucial importance to economies around the world. Read more
Computer Aided Engineering (CAE) covers the use of computers in all activities from the design to the manufacture of a product. It is at the forefront of information technology and of crucial importance to economies around the world. It is a vital part of many global industries including those of automotive, aerospace, oil, defence, finance and health. Computer Aided Engineering systems provide virtual product development environments allowing 3D models to be created, analysed, optimised and stored efficiently; operational and extreme physical conditions can be evaluated, reducing (and sometimes eliminating) the need for prototypes.

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This Mechanical Engineering MSc will enable you to develop your understanding and analytical skills in mechanical engineering. This qualification is internationally recognised and provides a wide range of career options. Read more
This Mechanical Engineering MSc will enable you to develop your understanding and analytical skills in mechanical engineering. This qualification is internationally recognised and provides a wide range of career options.

Our use of current and advancing computer aided techniques coupled with teaching informed through our collaborative links with industry assures a course fit for current and future industrial needs.

WHY CHOOSE THIS COURSE?

The course includes guest speakers from industry to deliver state-of-the-art information.

Projects undertaken on the course will offer students the opportunity to interact with companies and live research projects.

You will explore both theoretical and practical elements of mechanical engineering.

WHAT WILL I LEARN?

This course includes the following Core Topics:
-Masters Project (Industry or Acedemic based)
-Project Management
-Computer Aided Engineering
-Engineering Analysis and Simulation
-Stress & Dynamics
-Metrology and Lightweight Advanced Materials
-Thermofluid Systems
-Control Engineering
-Durability & Reliability

Students will study core mechanical sciences along with: design, control, manufacturing, materials, project management, and computer aided engineering.

HOW WILL THIS COURSE ENHANCE MY CAREER PROSPECTS?

A wide range of potential careers will be open to you on graduation including the opportunity to work as a mechanical engineer in automotive and aerospace industries.

You will learn to manage the process of industrial development which is essential to assure future commercial success.

Mechanical engineers are employed in all sectors of industrial operation and, in addition, their analytical and management skills are keenly sought in a wider commercial context.

GLOBAL LEADERS PROGRAMME

To prepare students for the challenges of the global employment market and to strengthen and develop their broader personal and professional skills Coventry University has developed a unique Global Leaders Programme.

The objectives of the programme, in which postgraduate and eligible undergraduate students can participate, is to provide practical career workshops and enable participants to experience different business cultures.

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This new engineering masters has been developed specifically for graduate engineers. Build your skills, knowledge and understanding of engineering design practice, modern design tools, and advanced engineering technologies. Read more
This new engineering masters has been developed specifically for graduate engineers. Build your skills, knowledge and understanding of engineering design practice, modern design tools, and advanced engineering technologies. Advance your professional competency and readiness to tackle complex engineering challenges, whilst fulfilling the educational requirements of the Chartered Engineer Standard (CEng).

Key features

-Designed so that graduate engineers can fulfil the educational requirements of the CEng Standard.
-Advance your professional competency and work place readiness.
-Develop a rigorous understanding of engineering design methodology; modern design tactics and practice; and the theory of technical systems.
-Acquire deeper understanding of computer aided engineering techniques; the modelling and analysis of engineering systems; and verification, validation and optimisation techniques.
-Deepen your knowledge and understanding of a technological subject or aspect of professional practice that is pertinent to your own professional development needs.
-Demonstrate innovation and creativity to solve a complex engineering problem in your dissertation project.
-Exploit the broad range of engineering research and technical facilities of the University.
-Study over one year full time or two years part time.

Course details

This programme (subject to validation) involves 180 credits of study at Level 7 with a flexibility to meet your individual development needs. The core modules in advanced engineering design will be complemented by negotiated study options and a 60 credit individual dissertation project.

The advanced engineering design modules will allow you to explore systems design, product modelling, design management, and the strategies and tactics of modern design practice. Through a project-based learning approach, you'll have the opportunity to develop competency in computer aided engineering and design optimisation tools. The negotiated study options allow you to deepen your knowledge of an engineering topic and/or professional practice, whilst the dissertation project will allow you to use your innovation and creativity to develop solutions to complex problems.

You'll be expected to maintain a record of your continuing professional development to assist you in your application for CEng.

Core modules
-MECH537 Advanced Engineering Design II
-MECH539 Computer Aided Engineering
-MECH541 Engineering Design Dissertation
-MECH542 Product Failure and Materials Optimisation
-MECH536 Advanced Engineering Design I

Optional modules
-MAR528 Mechanics of MRE Structures
-PRCE513 Interdisciplinary Design
-MECH543 Nanotechnology and Medical Engineering
-MECH544 Data Processing, Simulation and Optimisation of Engineering Systems

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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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The MSc in Advanced Process Integration and Design started in the Department of Chemical Engineering (UMIST) over twenty years ago. Read more
The MSc in Advanced Process Integration and Design started in the Department of Chemical Engineering (UMIST) over twenty years ago. The programme was a result of emerging research from the Centre for Process Integration, initially focused on energy efficiency, but expanded to include efficient use of raw materials and emissions reduction. Much of the content of the course stems from research related to energy production, including oil and gas processing.

The MSc in Advanced Process Integration and Design aims to enable students with a prior qualification in chemical engineering to acquire a deep and systematic conceptual understanding of the principles of process design and integration in relation to the petroleum, gas and chemicals sectors of the process industries.

Overview of course structure and content
In the first trimester, all students take course units on energy systems, utility systems and computer aided process design. Energy Systems develops systematic methods for designing heat recovery systems, while Utility Systems focuses on provision of heat and power in the process industries. Computer Aided Process Design develops skills for modelling and optimisation of chemical processes.

In the second trimester, the students choose three elective units from a range covering reaction systems, distillation systems, distributed and renewable energy systems, biorefining, and oil and gas processing. These units focus on design, optimisation and integration of process technologies and their associated heat and power supply systems.

In two research-related units, students develop their research skills and prepare a proposal for their research project. These units develop students skills in critical assessment of research literature, group work, written and oral communication, time management and research planning.

Students then carry out the research project during the third trimester. In these projects, students apply their knowledge and skills in process design and integration to investigate a wide range of process technologies and design methodologies. Recent projects have addressed modelling, assessment and optimisation of petroleum refinery hydrotreating processes, crude oil distillation systems, power plants, waste heat recovery systems, refrigeration cycles with mixed refrigerants, heat recovery steam generators, biorefining and biocatalytic processes and waste-to-energy technologies.

The course also aims to develop students' skills in implementing engineering models, optimisation and process simulation, in the context of chemical processes, using bespoke and commercially available software.

Industrial relevance of the course
A key feature of the course is the applicability and relevance of the learning to the process industries. The programme is underpinned by research activities in the Centre for Process Integration within the School. This research focuses on energy efficiency, the efficient use of raw materials, the reduction of emissions reduction and operability in the process industries. Much of this research has been supported financially by the Process Integration Research Consortium for over 30 years. Course units are updated regularly to reflect emerging research and design technologies developed at the University of Manchester and also from other research groups worldwide contributing to the field.

The research results have been transferred to industry via research communications, training and software leading to successful industrial application of the new methodologies. The Research Consortium continues to support research in process integration and design in Manchester, identifying industrial needs and challenges requiring further research and investigation and providing valuable feedback on practical application of the methodologies. In addition, the Centre for Process Integration has long history of delivering material in the form of continuing professional development courses, for example in Japan, China, Malaysia, Australia, India, Saudi Arabia, Libya, Europe, the United States, Brazil and Colombia.

Career opportunities

The MSc course in Advanced Process Design and Integration typically attracts 40 students; our graduates have found employment with major international oil and petrochemical companies (e.g. Shell, BP, Reliance and Petrobras and Saudi Aramco), chemical and process companies (e.g. Air Products), engineering, consultancy and software companies (e.g. Jacobs and Aspen Tech) and academia.

Accrediting organisations

This programme is accredited by the IChemE (Institution of Chemical Engineers).

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This MSc in Advanced Engineering Design is aimed at high calibre and ambitious engineering graduates who want to gain expertise in systematically developing complex, multidisciplinary engineering design. Read more

About the course

This MSc in Advanced Engineering Design is aimed at high calibre and ambitious engineering graduates who want to gain expertise in systematically developing complex, multidisciplinary engineering design.

You will learn how to design products requiring embedded intelligence and comprehensive engineering analysis and how to use six CAE software packages.

The programme - accredited by the Institution of Mechanical Engineering (IMechE) - has been developed to fulfil the industry’s need for an integrated course that offers:
teaching of advanced theory, human factors and creativity tools essential to successful product development
training in software, research and applications
practical experience of applying your knowledge and skills through an integrating, real life group project.

Aims

Integration of mechanical, electrical, electronic and control knowledge into a single product is challenging – and this course allows you to appreciate the complexity of modern product design and to develop your expertise.

The Brunel programme aims to create the new generation of engineering designers who can combine knowledge from different areas and produce world class design.

Engineering design is the application of engineering principles, the experience of making, and use of mathematical models and analysis. The design and production of complex engineering products often require the use of embedded intelligence and detailed engineering analysis involving mechanical, electronic and control functions. Advanced theoretical knowledge and a wide range of computer driven tools, methods and methodologies are essential for this process – and the course provides graduates with these essentials.

Course Content

Continued design of modern complex products demands advanced knowledge in mechanical, electronic, manufacturing and control engineering disciplines and human factors in design, and an ability to use advanced engineering software packages, integrating application experience and a capacity to carry on learning.

The Advanced Engineering Design MSc has been developed to produce design engineers who can meet these demands. It contains six taught modules where advanced multi-disciplinary theory is taught. As part of the course, six engineering software packages are also taught. In order to give an integrating application experience in an industrial setup, 'Design Experience', a group project module with an industry, has been included as part of the curriculum.

The dissertation is aimed at providing training in carrying out an in-depth engineering task on a self-learning basis. By the end of the course you will become a confident design engineer equipped with high quality and advanced knowledge and skills to work on design tasks in an advanced computer assisted environment.

Compulsory Modules

Sustainable Design and Manufacture
Manufacturing Systems Design and Economics
Computer Aided Engineering 1
Computer Aided Engineering 2
Design Experience
Dissertation Project

Optional Modules (choose two modules)

Advanced Manufacturing Measurement
Human Factors in Design
Robotics and Manufacturing Automation
Design of Mechatronic Systems

Special Features

Special facilities

MSc Engineering Design students work in a well-equipped design studio with various experiential learning facilities, with computers available for your exclusive use of Engineering Design students.Our investment in laboratory facilities and staff ensures that we can provide an excellent experience in a friendly and supportive environment.

Industry-focused programme

The high standard of our research feeds directly into curriculum design and our teaching, ensuring our graduates are equipped with the most up-to-date techniques, methods and knowledge bases. Our teaching has an excellent reputation and is orientated to the expressed needs of modern enterprises and the industry.
The course is underpinned by the current research still being carried out by the staff in the former academic unit Advanced Manufacturing and Enterprise Engineering which promotes manufacturing as a discipline.  Thus the academics teaching on the Advanced Engineering Design which were part of this unit have strong research portfolios in manufacturing. This research has been judged world leading.  In the 2014 Research Excellence Framework, academics teaching on the course were involved with Brunel’s General engineering submission, one of one of the largest in the UK. The area’s percentage of world leading research doubled, with a significant increase in our research judged as internationally excellent as well. The impact of over 75% of this research was judged to be world leading or internationally excellent. This placed the discipline in the top 20% in the UK terms of research power.

Global reputation

With around 150 postgraduate students from all around the world and substantial research income from the EU, research councils and industry, we are a major player in the field of advanced manufacturing and enterprise engineering.
 
Women in Engineering and Computing Programme

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

Accreditation

The MSc Advanced Engineering Design is accredited by both the Institution of Mechanical Engineering (IMechE). This will provide a route to Chartered Engineer status in the UK.

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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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The MSc in Integrated Product Design course focuses on the design of innovative products, emphasising the balance between the interest of users, industry and society. Read more

About the course

The MSc in Integrated Product Design course focuses on the design of innovative products, emphasising the balance between the interest of users, industry and society. It covers the whole design process, integrating all aspects relevant to product development, in particular global new product design.

It meets industrial demand by integrating technology, management, aesthetics, environmental sustainability, ergonomics, marketing, business and design methods – to produce highly qualified and sought after designers able to cope with the challenges the global economy presents.

Specifically, the course aims to:

Provide an integrated programme of study across a broad range of knowledge and skills in product/industrial design
Develop design and technology research skills related to the design process through practicing applied research
Develop advanced design skills, enabling graduates to practice as an independent design professional and to further develop design and professional skills in product/industrial design engineering
Nurture scientific rigour as well as creativity to enable graduates to follow a successful career in product/industrial design and assume leadership roles in national and international companies and institutions.

Aims

Students master all aspects of integrated product design advancing their design skills and knowledge by applying systematic state-of-the-art theories and methodologies, and by integrating user, technology and business aspects. This not only opens up dynamic career options, but equips students with a comprehensive skillset to take into the commercial world.

The primary aim of this programme is to provide students with the practical knowledge and transferable skills required to be at the forefront of global product and services design research and development, in either an industrial or academic environment.
Graduates of this MSc will also have the independent learning ability required for both continual professional development and the acquisition of new skills at the highest level.

The course provides an integrated approach and promotes advanced studies in design theory, creativity and aesthetics, innovation methods, advanced design techniques, human factors and applied ergonomics, engineering, material and production science, sustainability and research methods.

Course Content

The first term includes three taught modules worth a total of 45 credits plus one double module of 30 credits which continues into the second term alongside three further modules. The thick module, Professional Design Studio, will include guest lectures, research seminars and group or individual project. The projects can be based on design research or product/industrial design.

The ‘Design Futures’ module will introduce the importance and potential value of future foresight techniques and develop a vision of the future and critically evaluate its implications for design, innovation and enabling technology.

The ‘Computer Aided Design and Manufacturing Techniques’ module will introduce CAD and graphics based design modelling, rendering techniques and tools, product design simulation techniques and tools, rapid prototyping and manufacturing techniques.

For the final four months of the programme (June to September), students can either continue their projects to greater depth as their dissertation project, or undertake a new subject. Students are encouraged to form industrial links as part of this project.

Typical Modules

Sustainable Design
Design Creativity and Aesthetic Awareness
Human Factors in Design
Professional Design Studio
Design and Innovation Futures: Seminar & Workshop
Computer Aided Design and Manufacturing Techniques
Strategic Design Management and Research
Dissertation Project

Assessment

Work in each module is predominantly assessed through practical project assignments including both individual and group work. The dissertation makes up a third of the overall degree and may include a substantial practical design element, but in all cases will be assessed through a final 20,000 word submission.

Special Features

High league table standings: Our courses are among the highest-ranking for Product and Industrial Design in the UK. In all the most recent university guides, as well as in the National Student Survey, Brunel Design is placed in the top four out of all UK Art and Design courses.

High employability: Design graduates enjoy excellent career prospects – see student graduate articles.

Accreditation

Brunel's Integrated Product Design course is accredited by the Institution of Engineering Designers (IED).

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The programme has been designed to provide postgraduate education and training in Manufacturing Management. The course includes modules in topics such as Computer Aided Engineering, Quality and Manufacturing Systems. Read more
The programme has been designed to provide postgraduate education and training in Manufacturing Management. The course includes modules in topics such as Computer Aided Engineering, Quality and Manufacturing Systems. A significant proportion of the students on the course come from local engineering companies and study in a part-time mode. Both the MSc and PgDIP versions of the course are also suitable for engineering or science graduates wishing to up skill in order to improve their employment prospects.

Key benefits

- Accredited by the Institution of Engineering and Technology on behalf of the Engineering Council for the purposes of fully meeting the academic requirement for registration as a Chartered Engineer.

- Accredited by the Institution of Mechanical Engineers (IMechE) on behalf of the Engineering Council for the purposes of fully meeting the academic requirement for registration as a Chartered Engineer.

- Work placement available

Visit the website: https://www.ulster.ac.uk/course/msc-manufacturing-management-ft-j

Course detail

- Description -

The course draws upon the internationally recognised research within the school in areas such as Aerospace Composites, Polymers, Advanced Metal Forming, Medical Devices, Biomedical Engineering, and Nanotechnology. Such research within the school has led to several successful spinout companies. Staff teaching on the course also have a wealth of industrial experience with many have decades of experience working with a wide range of companies. The following represent some of the available taught modules: Core modules, Manufacturing Systems • Computer Aided Engineering for Engineers.

- Teaching and learning assessment -

The course is delivered through lectures, tutorials and laboratory classes and is supported with extensive online content. The small class sizes provide an excellent learning environment and the material is assessed thorough formal examinations, coursework, class tests and presentations.

- Work placement / study abroad -

Part-time students can undertake work based learning modules.

Career options

Upon successful completion of the programme students will be more employable within a wide range of manufacturing industries. The wide range of optional modules available in areas such as Biomedical Engineering, Nanotechnology, Aerospace and Materials allows students to tailor the course towards their particular interests. Another important opportunity for MSc students is the academic/research career through a PhD programme such as those offered in the Engineering Research Institute (ERI) which hosts the MSc programme.

How to apply: https://www.ulster.ac.uk/apply/how-to-apply#pg

Why Choose Ulster University ?

1. Over 92% of our graduates are in work or further study six months after graduation.
2. We are a top UK university for providing courses with a period of work placement.
3. Our teaching and the learning experience we deliver are rated at the highest level by the Quality Assurance Agency.
4. We recruit international students from more than 100 different countries.
5. More than 4,000 students from over 50 countries have successfully completed eLearning courses at Ulster University.

Flexible payment

To help spread the cost of your studies, tuition fees can be paid back in monthly instalments while you learn. If you study for a one-year, full-time master’s, you can pay your fees up-front, in one lump sum, or in either five* or ten* equal monthly payments. If you study for a master’s on a part-time basis (e.g. over three years), you can pay each year’s fees up-front or in five or ten equal monthly payments each year. This flexibility allows you to spread the payment of your fees over each academic year. Find out more by visiting https://www.ulster.ac.uk/apply/fees-and-finance/postgraduate

Scholarships

A comprehensive range of financial scholarships, awards and prizes are available to undergraduate, postgraduate and research students. Scholarships recognise the many ways in which our students are outstanding in their subject. Individuals may be able to apply directly or may automatically be nominated for awards. Visit the website: https://www.ulster.ac.uk/apply/fees-and-finance/scholarships

English Language Tuition

CELT offers courses and consultations in English language and study skills to Ulster University students of all subjects, levels and nationalities. Students and researchers for whom English is an additional language can access free CELT support throughout the academic year: https://www.ulster.ac.uk/international/english-language-support

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The MSc Technical Architecture provides advanced level study in contemporary technical, environmental and professional issues for architecture. Read more

The MSc Technical Architecture provides advanced level study in contemporary technical, environmental and professional issues for architecture. You work on design-led projects focusing on the creative and technical consideration of architecture, and carry out a range of applied projects to develop professional skills.

Core modules provide key knowledge and skills, which are then applied to design projects. Lectures and projects look at emerging theory and practice in architectural design, technology and construction for new and existing buildings within the UK and global contexts.

All modules address contemporary issues in architecture. There is a focus on environmental and sustainable design and how they are achieved through inventive thinking, creative technical design, scientific understanding and computer aided predictive modelling. You learn to use design software including REVIT, ArchiCad and Ecotect.

The course assessments are flexible so you develop your own areas of interest and expertise. Projects can be located in your home country, either in the UK or internationally, or you can explore alternative locations.

The part-time route enables you to work and study at the same time, and you can link your projects to your practice.

In the final stage of the course you produce an original and significant piece of research-led design in the major project module, supported by a research module. This is usually in a subject relevant to your area of architectural interest, technical specialism or practice. You use these concluding modules to identify and develop critical expertise for your chosen career.

The course has a strong professional focus. A key feature is an international field trip as part of the interdisciplinary practice module, which you study alongside students in associated professions such as planning, regeneration, real estate and surveying. Other professional modules allow you to work as a consultant to a real client or to study new or alternative forms of computer aided design.

The course is versatile in its teaching approaches and provides educational and professional development opportunities for a range of applicant profiles. These include UK and international students with architecture, construction or environment related degree qualifications and mature applicants with a proven track record in practice.

You are taught by an expert team of staff that includes experienced architectural, digital and environmental practitioners and academics. We also have teaching links with leading consulting engineers such as ARUP and Price and Myers.

Professional recognition

This programme has been recognised by the Chartered Institute of Architectural Technologists (CIAT) as meeting established standards in terms of course content and qualifies the holder for associate membership of the institute (ACIAT).

CIAT recognises Sheffield Hallam University as an accredited Centre of Excellence for learning and teaching in architectural technology.

Course structure

Full time – September start – typically 12 months

Full time – September start – typically 16 months

Part time – September start – typically 36 months

Core modules

  • concepts and design in technical architecture (30 credits)
  • environmental theory and practice for technical architecture (30 credits)
  • fundamentals of building information modelling (15 credits)
  • applied research methods (15 credits)
  • major project (45 credits)

Option modules

  • interdisciplinary practice (15 credits)
  • contemporary digital practice in architecture (15 credits)
  • consultancy project (15 credits)
  • historic environments and design (15 credits)
  • academic and professional portfolio (15 credits). 

Assessment

  • design projects
  • technical and environmental studies
  • digital modelling
  • essays
  • report writing
  • group projects
  • presentations
  • research reports
  • dissertation or major design project

Employability

The course provides knowledge and skills for a range of careers. These can include senior positions in architectural practice, setting up your own company or moving into college or university level teaching.

Specialist careers include • architectural conservation • practice management • digital design • environmental design and consultancy.

You can also use the course to move from your current career into a more architecture-related one. This is particularly relevant if you currently work in areas such as building surveying, construction or some forms of engineering.



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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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Study at the forefront of ground-breaking innovation with word-leading researchers. We’ll equip you to think adventurously, overcome problems and be part of the process of enabling society to advance. Read more
Study at the forefront of ground-breaking innovation with word-leading researchers. We’ll equip you to think adventurously, overcome problems and be part of the process of enabling society to advance. You’ll test your practical skills in our brand new industry standard workshop.

You’ll gain an in-depth understanding of advanced design and analysis techniques, the use of modern materials and manufacturing technology. We’ll expand your knowledge in a wide range of mechanical engineering areas and related fields, giving you the scope to be creative and scientific in equal measure.

Our course will equip you with transferrable skills, including IT and management as well as data analysis. As a result you’ll be highly employable in the mechanical engineering marketplace, with a choice of different careers available to you.

Full-time - January start, 15 months. September start, 12 months.
Part-time - January start, 33 months. September start, 28 months.

See the website http://www.anglia.ac.uk/study/postgraduate/mechanical-engineering

Careers

Our course will help you find your career in engineering, or give you an additional skills boost if you’re already working in the industry. You may want to work directly in engineering and design or use this degree as a step towards a career in a related area, such as consultancy. You’re also in the perfect position to continue your academic career and move up to our Mechanical Engineering PhD.

Core modules

Computer Aided Engineering Analysis
Biomechanics
Automation and Robotics
Computational Fluid Dynamics
Innovative Product Design and Manufacture
Advanced Materials and Structural Integrity
Research Design and Methods
Dissertation

Assessment

You’ll be assessed in a variety of ways, including written assignments, portfolios, presentations, examinations and a dissertation.

Your faculty

The Faculty of Science & Technology is one of the largest of five faculties at Anglia Ruskin University. Whether you choose to study with us full- or part-time, on campus or at a distance, there’s an option whatever your level – from a foundation degree, to a BSc, MSc, PhD or professional doctorate.

Whichever course you pick, you’ll gain the theory and practical skills needed to progress with confidence. Join us and you could find yourself learning in the very latest laboratories or on field trips or work placements with well-known and respected companies. You may even have the opportunity to study abroad.

Everything we do in the faculty has a singular purpose: to provide a world-class environment to create, share and advance knowledge in science and technology fields. This is key to all of our futures.

Specialist facilities

Studying at our Chelmsford campus, you’ll have access to a comprehensive range of engineering facilities. These include our CADCAM centre, industrial scale CNC milling machine, CNC lathe, rapid prototyping machine, scanning electronic microscope, Instron bi-axial fatigue testing machine, tensile testing machine, material preparation facilities, welding equipment, various mechanical machines, various electronic testing and measuring equipment such as oscilloscopes, and signal generating/ testing facilities. You’ll also be able to access our materials lab and our computer aided engineering lab, our libraries, and open access computer suites.

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Innovation in product design and manufacturing has become a major driver for industrial competitiveness and profitablity in recent years. Read more
Innovation in product design and manufacturing has become a major driver for industrial competitiveness and profitablity in recent years. As enabling technologies become more easily accessible, engineers are faced with increasing demands for designing and producing more complex mechanical devices to serve the needs of the society. Next generation engineering products will be ‘smart’ with many functionalities; they will be made of new materials; they will increase energy efficiency and reduce environmental impact; they will vary in size from nano to mega scales; and they will be more closely integrated with information processing systems. Also as mechanical systems are becoming increasingly complex to analyze and expensive to experiment, more emphasis will have to be placed on computer aided analysis, design, verification and manufacturing. Our research program in mechanical engineering responds to these trends and focuses on basic research related to materials science and process engineering, product design, and information integrated manufacturing processes. In doing so applications to different physical processes are studied (e.g. energy systems, bioengineering, metal forming, polymer processing, discrete part manufacturing to name a few).

Current faculty projects and research interests:

• Computer Aided Numerical Control (CNC) Systems and Machine Tools
• Automation and Mechatronics
• Composite Materials Manufacturing
• Human and Machine Haptics
• Multi-Scale Experimental and Computational Mechanics of Materials
• Bioinspired and Biological Fluid Mechanics
• Cardiovascular Mechanics
• Vibrations and Structural Dynamics
• Modelling and Design of Micro /Macro Systems
• Computational Materials Science (Polymers, Biomaterials, Shape
Memory Alloys)
• Computational Fluid Dynamics
• Thermal and Bio/Micro Fluidic Systems
• Micro-Nano Electromechanical Systems (MEMS/NEMS)
• Microstructure Evolution Dynamics (Solidication, Crystal Groeth)
• Control systems and Robotic

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This course is for engineers or graduates who want to become technical specialists or managers in industrial and manufacturing companies. Read more

This course is for engineers or graduates who want to become technical specialists or managers in industrial and manufacturing companies.

It increases your career potential by improving your

  • knowledge and experience of engineering
  • technical and problem solving skills
  • management skills
  • ability to take on greater responsibility

This course helps you understand concepts and theories behind developing, manufacturing and managing engineering products and systems. You learn to explore and apply developments in engineering and management academic thinking and industrial practice.

You study

  • two management modules
  • two technical modules
  • four optional modules

There is a wide range of optional modules including • lean operations and six sigma • advanced manufacturing technology • applicable artificial intelligence • computer-aided design/computer-aided manufacture • advanced computer system architecture • network applications.

The international product development module involves working in multidisciplinary teams to develop a new product in a global market. This allows you to develop much sought after advanced technical and business skills and improves your career prospects in engineering industry, and public service. This project also develops your particular interest in a supported environment.

Professional recognition

This course is accredited by the Institute of Materials, Minerals and Mining (IOM3), on behalf of the Engineering Council, for the purposes of partly meeting the academic requirement for registration as a Chartered Engineer; graduates who have a BEng (Hons) accredited for CEng will be able to show that they have satisfied the further learning requirement for CEng accreditation.

This course is also accredited by the Institution of Mechanical Engineers (IMechE) on behalf of the Engineering Council and 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. It should be noted that graduates from an accredited MSc programme, who do not also have an appropriately accredited Honours degree, will not be regarded as having the exemplifying qualifications for professional registration as a Chartered Engineer with the Engineering Council; and will need to have their first qualification individually assessed through the Individual Case Procedure if they wish to progress to CEng.

This programme is CEng accredited by the Institution of Engineering and Technology (IET) and fulfils the educational requirements for registration as a Chartered Engineer when presented with an CEng accredited Bachelors programme.

Course structure

Core management modules

  • Finance and marketing
  • Project and quality management

Core technical modules

  • Group project – international product development
  • Sustainability, energy and environmental management

Optional modules

Two from

• lean operations and six sigma • management of strategy, change and innovation • manufacturing systems

plus two from

• advanced control methods • advanced investigatory techniques for materials engineers • advanced manufacturing technology • advanced metallic materials • advanced vibration and acoustics • applicable artificial intelligence • computer-aided design/computer-aided manufacturing • communication engineering • communication media • computer networks • competitive design for manufacture • competitive materials technology • control of linear systems • digital electronics system design • digital signal processing • embedded systems • equipment engineering and design • industrial applications of finite element methods • industrial automation • machine vision • microprocessor engineering • advanced computer system architecture • network applications • object-oriented methods • operating systems • robotics • software engineering • VSLI

MSc

  • Project and dissertation

Assessment

  • examination
  • coursework
  • project reports

Employability

If you are a new graduate, this course gives you the knowledge and skills to begin a career as a technical specialist or manager. If you are already employed in engineering, it improves you career potential and can lead to roles with greater responsibility.

It can also help towards a career teaching engineering.



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