• University of Derby Online Learning Featured Masters Courses
  • Goldsmiths, University of London Featured Masters Courses
  • Xi’an Jiaotong-Liverpool University Featured Masters Courses
  • Cardiff University Featured Masters Courses
  • Coventry University Featured Masters Courses
  • New College of the Humanities Featured Masters Courses
  • University of Glasgow Featured Masters Courses
  • St Mary’s University, Twickenham Featured Masters Courses
London School of Hygiene & Tropical Medicine Featured Masters Courses
Leeds Beckett University Featured Masters Courses
University of Bradford Featured Masters Courses
Barcelona Executive Business School Featured Masters Courses
Bath Spa University Featured Masters Courses
0 miles
Engineering×

City, University of London, Full Time MSc Degrees in Engineering

  • Engineering×
  • City, University of London×
  • MSc×
  • Full Time×
  • clear all
Showing 1 to 7 of 7
Order by 
Develop your knowledge, design and analysis skills, engage with modern challenges in structural engineering and transform your professional profile with this accredited technical MSc in Civil Engineering Structures. Read more
Develop your knowledge, design and analysis skills, engage with modern challenges in structural engineering and transform your professional profile with this accredited technical MSc in Civil Engineering Structures.

Who is it for?

This course is for professional engineers who want to specialise in structural engineering or move into this area of expertise to advance their career. Normally students have an undergraduate degree in engineering or a related discipline. Students who don’t have qualifications in civil engineering usually have relevant work experience in civil engineering structures so they are familiar with working within the specific technical domain.

Objectives

From analysing how carbon nanofibers can reduce the effect of corrosion in concrete to gaining insight from experts developing the new Forth Bridge, this MSc in Civil Engineering Structures has been designed to be broad in scope so you can develop your own area of structural engineering expertise.

As a department, we have broad interests from defining new structural forms to practical application of new materials. We believe civil engineering is a creative and collaborative profession, as much as a technical one. This course gives you the tools to immerse yourself in both the analytical and experimental side of the subject, so you can investigate diverse problems to generate your own structural solutions.

The Civil Engineering Structures MSc mirrors industry practice, so you will work in groups with your peers from the first term onwards and learn from a group of world-leading engineers with diverse research strengths. From earthquake engineering to sustainable construction, you have the opportunity to learn in breadth and depth using high-end industry software to develop safe solutions for real-world projects.

Academic facilities

There is a large dedicated lab on site equipped with facilities to investigate different structures and construction materials from concrete to timber. You also have access to other workshops where you can liaise with mechanical or electrical engineers to develop innovative scale models. There is access to specialist soil labs and large-scale equipment including wind tunnels.

We have an extensive library housing all the references, journals and codes of practice that you will need during your studies.

As part of the University of London you can also become a member of Senate House Library for free with your student ID card.

Teaching and learning

You will be taught by the staff team within the School of Mathematics, Computer Science and Engineering and also from visiting industry experts from around the world.

Teaching mainly takes the form of lectures, but IT sessions and seminars also form part of the Masters degree. Modules are shared between two ten-week teaching terms running from October to December and January to March. Although work for the MSc dissertation starts during the second term, you will conduct most of the research work during the summer months.

The length of the full-time degree is 12 months. A part-time route is also available where you can spend either two or three years completing the programme. If you follow the two-year part-time study route, you will need to attend lectures for up to two days each week. Alternatively, you can complete the degree over three years by attending a single day each week. The timetable has been designed to offer flexibility for part-time students.

In the first term you will consider core technical topics and be introduced to new concepts such as structural reliability. In the second term you will begin to focus your studies by selecting your dissertation topic and by selecting options getting involved in a specific areas of your own interest. Spread over the year you will have design presentations, class tests and reports.

If you select an experimental dissertation you will have the opportunity to use a range of materials. Skilled technical support is available in the workshop and you have access to recently refurbished facilities, including specialist geotechnical labs which accommodate a large flexible laboratory space used for centrifuge model preparation and testing. Adjacent to this you have concrete mixing and casting facilities, a temperature-controlled soil element testing laboratory and a concrete durability laboratory.

Assessment

For the theoretical modules, you will be assessed through a combination of examinations and coursework. Examinations are shared between the January and April/May examination periods. For the design-oriented modules you are normally assessed by coursework only, where you will work both in groups and individually on challenging projects.

Modules

There are six core modules which give you a strong technical foundation and three elective modules from which you can choose two. These reflect the specialist expertise on offer within the academic team. These modules will give you unique insight into computer analysis of structures for blast and fire, bridge engineering, and earthquake analysis where you may look at techniques for analysing structures and safe design. In the final part of the programme you undertake a dissertation in which you can explore an area of interest from a proposed list of themes, some of which are industry-related.

Core modules and dissertation
-Advanced structural analysis and stability (20 credits)
-Finite element methods (15 credits)
-Dynamics of structures (15 credits)
-Structural reliability and risk (10 credits)
-Design of concrete structures (15 credits)
-Design of steel and composite structures (15 credits)
-Dissertation for MSc degree (Research Skills and Individual Project) (60 credits)

Elective modules - you will be able to study two of the following elective modules:
-Earthquake analysis of structures (15 credits)
-Analysis of steel and concrete structures for blast and fire exposure (15 credits)
-Bridge engineering (15 credits)

Career prospects

Graduates have secured employment with leading civil engineering consultants, research institutes and government agencies and pursued doctoral studies both in the UK and internationally. The cohort of 2014 have moved on to jobs and further study working within the following organisations:
-WSP Consultant Engineers
-Tully De'Ath Consultant Civil and Structural Engineers
-SSA Consulting Engineers
-Bradbrook Consulting
-Clarke Nicholls Marcel

Read less
Make future breakthroughs within healthcare with the MSc Biomedical Engineering with Healthcare Technology Management course. This course is for inquisitive students who want to design, develop, apply or even manage the use of cutting-edge methods and devices that will revolutionise healthcare. Read more
Make future breakthroughs within healthcare with the MSc Biomedical Engineering with Healthcare Technology Management course.

Who is it for?

This course is for inquisitive students who want to design, develop, apply or even manage the use of cutting-edge methods and devices that will revolutionise healthcare. It is open to science and engineering graduates and those working within hospitals or related industry who want to work in healthcare organisations, in the medical devices industry, or in biomedical engineering research.

The course will suit recent graduates and/or clinical engineers with a technical background or those working in healthcare who want to move into a management position.

Objectives

With several medical conditions requiring extensive and continuous monitoring and early and accurate diagnosis becoming increasingly desirable, technology for biomedical applications is rapidly becoming one of the key ingredients of today and tomorrow’s medical care.

From miniaturised home diagnostic instruments to therapeutic devices and to large scale hospital imaging and monitoring systems, healthcare is becoming increasingly dependent on technology. This course meets the growing need for biomedical and clinical engineers across the world by focusing on the design of medical devices from conception to application.

One of the few accredited courses of its kind in London, the programme concentrates on the use of biomedical-driven engineering design and technology in healthcare settings so you can approach this multidisciplinary topic from the biological and medical perspective; the technological design and development perspective; and from the perspective of managing the organisation and maintenance of large scale equipment and IT systems in a hospital.

This MSc in Biomedical Engineering with Healthcare Technology Management course has been created in consultation and close collaboration with clinicians, biomedical engineering researchers and medical technology industrial partners. The programme fosters close links with the NHS and internationally-renowned hospitals including St. Bartholomew's (Barts) and the Royal London Hospital and Great Ormond street so that you can gain a comprehensive insight into the applied use and the management of medical technology and apply your knowledge in real-world clinical settings.

Placements

In the last few years there have been some limited opportunities for our top students to carry out their projects through placements within hospital-based healthcare technology groups or specialist London-based biomedical technology companies. Placement-based projects are also offered to selected students in City’s leading Research Centre for Biomedical Engineering (RCBE). As we continue our cutting-edge research and industrial and clinical collaborations, you will also have this opportunity.

Academic facilities

As a student on this course you will have the opportunity to work with cutting-edge test and measurement instrumentation – oscilloscopes, function generators, analysers – as well as specialist signal generators and analysers. The equipment is predominantly provided by the world-leading test and measurement equipment manufacturer Keysight, who have partnered with City to provide branding to our electronics laboratories. You also have access to brand new teaching labs and a dedicated postgraduate teaching lab. And as part of the University of London you can also become a member of Senate House Library for free with your student ID card.

Teaching and learning

You will be taught through face-to-face lectures in small groups, where there is a lot of interaction and feedback. Laboratory sessions run alongside the lectures, giving you the opportunity to develop your problem-solving and design skills. You also learn software skills in certain modules, which are taught inside computer labs. We also arrange hospital visits so you gain hands-on experience of different clinical environments.

We arrange tutorials for setting coursework, highlight important subject areas, conduct practical demonstrations, and offer support with revision. You are assessed by written examinations at the end of each term, and coursework assignments, which are set at various times throughout the term.

You also work towards an individual project, which is assessed in the form of a written thesis and an oral examination at the end of the summer. The project can be based on any area of biomedical engineering, telemedicine or technology management and will be supervised by an academic or clinical scientist with expertise in the subject area. Many projects are based in hospital clinical engineering departments, or if you are a part-time student, you can base the project on your own workplace. You will have regular contact with the supervisor to make sure the project progresses satisfactorily. Some of the programme’s current students are working on a project focusing on devices that use brain signals to move external objects such as a remote control car and a prosthetic arm.

Some of the previous projects students have worked on include:
-A cursor controller based on electrooculography (EOG)
-Modelling a closed-loop automated anaesthesia system
-Design of a movement artefact-resistant wearable heart rate/activity monitor
-Review of progress towards a fully autonomous artificial mechanical heart
-Design of smartphone-based healthcare diagnostic devices and sensors.

If you successfully complete eight modules and the dissertation you will be awarded 180 credits and a Masters level qualification. Alternatively, if you do not complete the dissertation but have successfully completed eight modules, you will be awarded 120 credits and a postgraduate diploma. Completing four modules (60 credits) will lead to a postgraduate certificate.

Modules

Along with the 60 credit dissertation eight core modules cover diverse subject areas including biomedical electronics and instrumentation, technology infrastructure management, as well as the latest advances in medical imaging and patient monitoring.

The course includes a special module which gives you an introduction to anatomy, physiology and pathology designed for non-clinical science graduates.

The most innovative areas of biomedical and clinical engineering are covered and the content draws from our research expertise in biomedical sensors, bio-optics, medical imaging, signal processing and modelling. You will learn from academic lecturers as well as clinical scientists drawn from our collaborating institutions and departments, which include:
-Charing Cross Hospital, London
-The Royal London Hospital
-St Bartholomew's Hospital, London
-Basildon Hospital
-Department of Radiography, School of Community and Health Sciences, City, University of London

Modules
-Anatomy, Physiology and Pathology (15 credits)
-Physiological Measurement (15 credits)
-Biomedical Instrumentation (15 credits)
-Medical Electronics (15 credits)
-Cardiovascular Diagnostics and Therapy (15 credits)
-Medical Imaging Modalities (15 credits)
-Clinical Engineering Practice (15 credits)
-Healthcare Technology Management (15 credits)

Career prospects

This exciting MSc programme offers a well-rounded background and specialised knowledge for those seeking a professional career as biomedical engineers in medical technology companies or research groups but is also uniquely placed for offering skills to clinical engineers in the NHS and international healthcare organisations.

Alumnus Alex Serdaris is now working as field clinical engineer for E&E Medical and alumna Despoina Sklia is working as a technical support specialist at Royal Brompton & Harefield NHS Foundation Trust. Other Alumni are carrying out research in City’s Research Centre for Biomedical Engineering (RCBE).

Applicants may wish to apply for vacancies in the NHS, private sector or international healthcare organisations. Students are encouraged to become members of the Institute of Physics and Engineering in Medicine (IPEM) where they will be put in touch with the Clinical Engineering community and any opportunities that arise around the UK during their studies. Application to the Clinical Scientist training programme is encouraged and fully supported.

The Careers, Student Development & Outreach team provides a professional, high quality careers and information service for students and recent graduates of City, University of London, in collaboration with employers and other institutional academic and service departments. The course also prepares graduates who plan to work in biomedical engineering research and work within an academic setting.

Read less
A brand new, one of its kind qualification for those seeking specialist skills in the design and construction of temporary works. Read more
A brand new, one of its kind qualification for those seeking specialist skills in the design and construction of temporary works.

Who is it for?

This MSc degree is aimed at graduates with at least two years of practical experience in construction; however, more recent graduates with a good appreciation of construction processes will also benefit.

Having achieved a firm grounding in engineering you may be keen to develop your skills as a practical engineer working on site or enhance design skills if you are engaged in permanent works design.

Objectives

The course provides the following:
-An introduction to statutory obligations, management methods and special design considerations for temporary works.
-Design of structures used in and for temporary works, their construction and monitoring.
-Design of geotechnical temporary works and processes, including groundwater control and ground investigation.
-Design of temporary works for marine construction, in particular floating structures and the effect of waves and varying water levels.
-The use of plant in temporary works and the provision of appropriate working platforms and access.
-Demolition and alteration of structures, including the disposal/reuse of construction waste.

Teaching and learning

The learning and teaching approach for the course encompasses a range of methods which support active learning including lectures, workshops, group work, case studies, problem-based learning, presentations and peer review.

Workshops, group work, case studies and problem-based learning will be used to build your ability to critically review and assess options for design and assessment of temporary works. Your learning will be supported by the online learning environment Moodle, which will provide resources for independent learning, such as further reading, links to wider sources of information and quizzes for self-assessment.

All modules involve undertaking a certain number of individual and/or group assignments (coursework) during the teaching terms, as well as comprehensive final examinations.

Part-time students are expected to complete all the modules within the two-year period. The teaching periods are structured to deliver core modules in a sequence, which permits engagement by part-time students alongside full-time students. The project is undertaken by part-time students in the second year.

Teaching normally takes place on two full days per week, although there may be some variations to accommodate practical exercises and site visits. In addition, there is an introduction week at the start of the programme each year which is attended by all full and part-time students.

This method of delivery is designed to accommodate students working full-time within reasonable commuting distance of City, University of London, as well as to full-time students, by concentrating tuition into two days per week on average, and encouraging flexibility for independent study.

Modules

Temporary works refers to works enabling the construction of, protection, support or provision of access to permanent works which might or might not remain in place at the completion of a construction project. Examples of temporary works include structures such as gantries for heavy plant, materials or accommodation as well as supports for partially-completed or partially-dismantled structures, excavations and accesses. The course delivery and content is actively supported by the Temporary Works Forum (TWf), which promotes best practice within the UK construction industry and sponsors the Centre of Excellence in Temporary Works and Construction Method Engineering at City, University of London. The course content has been developed in collaboration with the TWf membership and TWf members will contribute to lectures and design exercises.

The course addresses the regulatory background to temporary works for construction, the design of geotechnical, structural and marine temporary works, demolition, plant, safe working methods and access works. You will gain both the technical understanding to undertake safe but cost-effective designs for a full range of temporary works and a good understanding of the wide range of plant and techniques that can be employed.

The programme will be delivered by industry experts providing insights into current practice in temporary works and academic members of staff experienced in the theory underlying the design methods employed. There will be visits to operational sites and practical exercises to provide opportunities to experience decision-making in the field, combined with group sessions to develop your knowledge further through active engagement. This will also require you to present your work occasionally, participate in peer review sessions and work in teams.

The course consists of eight taught modules and a project. The project is a major individual research exercise on a topic relevant to temporary works and construction method engineering. The main outcome of the project is a written report (dissertation).

Taught modules - the Temporary Works and Construction Method Engineering MSc comprises 180 credits, with 60 credits awarded to the project. Attendance is required to obtain 120 credits by studying all of the taught modules.

The taught modules address the following topics:
-An introduction to statutory obligations, management methods and special design considerations for temporary works.
-Design of structures used in and for temporary works, their construction and monitoring.
-Design of geotechnical temporary works and processes, including groundwater control and ground investigation.
-Design of temporary works for marine construction, in particular floating structures and the effect of waves and varying water levels.
-The use of plant in temporary works and the provision of appropriate working platforms and access.
-Demolition and alteration of structures, including the disposal/reuse of construction waste.

Project - the topics/titles for the major project can be chosen from:
-A list suggested by the lecturers of the course.
-Your own ideas/initiatives.
-Where applicable, by your sponsoring company/industrial partner.

Our collaboration with members of the TWf means that many of the topics offered will relate to problems of current interest to industry and will be co-supervised by industry organisations.

Career prospects

Temporary works are an important aspect of most construction projects. Consequently, a qualification in this field will have widespread application across all civil engineering disciplines, whether you are working as an on-site engineer or as a design office engineer. You could also go into the research arena conducting innovative research in the area of temporary works.

Read less
The MSc Mechanical Engineering programme provides practical skills and an understanding of fundamental theory to prepare students for the rapidly changing global market. Read more
The MSc Mechanical Engineering programme provides practical skills and an understanding of fundamental theory to prepare students for the rapidly changing global market.

Who is it for?

The programme is aimed at both new graduates and engineering professionals who wish to develop advanced skills in thermofluid, structural analysis, heat conversion and recovery, design and technology that are taught by leading experts in the field; all modules are updated by the latest advancements in technology.

This course is designed to meet the challenges of the rapidly changing global market; with the focus on well-designed systems and processes that are key to successful commercial enterprises.

Objectives

This course provides a broad-based knowledge of the latest technological developments in mechanical engineering. This includes thermos-fluids, structural mechanics, renewable energy, gas turbine, IC engines and advanced heat transfer.

Students not only gain an in-depth understanding on fundamental theory, but also acquire practical skills and can appreciate impending developments in the Mechanical fields of technology.

The Dissertation provides a stimulating and challenging opportunity to apply knowledge and develop a deep understanding in a specialised aspect of your choice. Dissertations can be institution or industry based and company sponsored students have the opportunity to develop their career. Successful industrial projects often lead to the recruitment of students by the collaborating company.

Teaching and learning

The programme comprises lectures, assessed assignments and technical visits.

Teaching by academics and industry professionals whose work is internationally recognised. Seminar series and talks are conducted by visiting speakers.

Assessment

Assessment is based on marks obtained throughout the year for courseworks, class tests, and end-of-year examinations. Modules, based on coursework only, are assessed through substantial individually designed courseworks, assignments and small projects. IT skill is assessed through submitted work on CATIA design reports and computational courseworks.

Modules

There are eight taught modules equating to 120 credits, plus a dissertation of 60 credits. The taught part of the MSc is structured into modules of 15 credits each.

The mode of delivery will follow a weekly teaching structure delivered at City, distributed through the year at the rate of four days per week. This course develops the broad skills and knowledge base required by mechanical engineers and provides a platform for career development.

Completion of modules and examinations will lead to the award of a Postgraduate Diploma. The completion of modules, examinations and dissertation will lead to the award of a Masters degree. Specialisations include computer-aided design, energy systems and management, combustions, IC engines, screw compressors and expanders, experimental techniques, mechatronics and dynamics of structures.

Core modules - 6 Core Modules, 15 credits each (90 credits):
-MEM102 Combustion Fundamentals and Applications (15 credits)
-MEM106 Advanced Structural Mechanics (15 credits)
-MEM107 Advanced Heat Transfer (15 credits)
-MEM108 IC engines and Vehicle Propulsion (15 credits)
-AEM301 Advanced Computational Fluid Dynamics (15 credits)
-AEM305 Gas Turbine Engineering (15 credits)
-Plus the individual project (EPM698) (60 credits)

Elective modules - Elective modules, choice of two, 15 credits each (30 credits):
-EPM707 Finite Element Methods (15 credits)
-EPM767 Mathematical Modelling in CAD (15 credits)
-EPM770 Renewable Energy (15 credits)
-EPM501 Power Electronics (15 credits)

Career prospects

Recent employment destinations of graduates include:
-Ford
-Rolls Royce
-Lotus
-BP
-Howden
-Shell
-Heliex
-Sortex
-Transport for London
-Jaguar
-Toyota
-Delphi
-Holroyd

Read less
Supported by the Royal Academy of Engineering, this MSc in Civil Engineering Structures (Nuclear Power Plants) is the only accredited course in the UK in this critical area. Read more
Supported by the Royal Academy of Engineering, this MSc in Civil Engineering Structures (Nuclear Power Plants) is the only accredited course in the UK in this critical area.

Who is it for?

This course is for students interested in the structural aspects of nuclear power plants and the broader field of nuclear energy.

Objectives

In this programme, you will study how to design, evaluate, and analyse structural systems, with a special focus on Nuclear Power Plants. You will learn all the principles used for the design of buildings, bridges, special structures and in particular nuclear containment structures.

The emphasis on nuclear structures is a response to the skill shortage reported by employers working in this sector. The UK has recently committed to a long-term nuclear new-build programme that is forecast to generate more than 40,000 jobs, yet no specialised training is available in this area. The programme will therefore provide you with a degree that distinguishes you in the market.

The programme is offered on a one-year full-time or two-year part time basis to allow you maximum flexibility.

Teaching and learning

The course is taught by staff from the School of Mathematics, Computer Science and Engineering with some contribution from industrial experts. Teaching is mainly in the form of lectures, but case studies and IT sessions and seminars are also used where appropriate. Modules are shared between two ten-week teaching terms running October-December and January-March. Although work for the MSc dissertation commences during the second term, most of the research work is carried out during the summer months.

The duration of full-time study is 12 months. A part-time route is also available, where students spend two years completing this programme, in which students attend lectures for up to two days each week

Assessment of theoretical modules is based on a combination of examinations and coursework. Examinations are shared between the January and April/May examination periods. Design-oriented modules are normally assessed by coursework only, where students work both in groups and individually on challenging projects that are varied each year. For the MSc dissertation, students are required to attend a viva following submission of the final report.

In order to pass your programme, you should complete successfully or be exempted from the relevant modules and assessments and will therefore acquire the required number of credits.

The pass mark for each module is 50%. You need to attain a 50% mark for all assessment components.

Modules

There are seven core modules to be taken, plus one elective module, in addition to the research skills module and the dissertation. The number and credits required to gain an award are identified below.

For the following modules: EPM717, EPM711, EPM712, EPM707, EPM720, EPM718, coursework assignments will require you to apply the theory you have learned to specialised problems relating to the field of nuclear power plants. You are required to answer these problems to satisfy the coursework assessment for these modules.

Core modules
-EPM790: Introduction to Nuclear Energy (10 credits)
-EPM717: Advanced Analysis and Stability of Structures (20 credits)
-EPM704: Dynamics of Structures (15 credits)
-EPM711: Design of Concrete Structures (15 credits)
-EPM712: Design of Steel and Composite Structures (15 credits)
-EPM791: Design of Nuclear Structures and Foundations (15 credits)
-EPM707: Finite Element Methods (15 credits)
-EPM697: Research Skills (15 credits)
-EPM698: Dissertation (45 credits)

Elective modules
-EPM720: Earthquake Analysis of Structures (15 credits)
-EPM718: Analysis of Steel and Concrete Structures for Blast and Fire Exposure (15 credits)

Career prospects

This programme is for students interested in the structural aspects of nuclear power plants. Your career will take you to the broader field of nuclear energy. The types of roles we would expect our graduates to achieve are: an on-site engineer or as a design office engineer, building designing or constructing new plants or evaluating and maintaining existing plants or decommissioning plants at the end of their life cycle. You could also go to the research arena conducting innovative research in the area of nuclear science at research labs or in academia.

Read less
This course has been designed to meet the industrial demand for the training and education of both existing and future engineers in the advanced concepts of sustainable electrical power and energy generation. Read more
This course has been designed to meet the industrial demand for the training and education of both existing and future engineers in the advanced concepts of sustainable electrical power and energy generation.

Who is it for?

This course is suitable for both practicing engineers and those considering a career in engineering.

The course has been designed to provide an in-depth insight into the technical workings, management and economics of the electrical power industry.

Objectives

This programme has been designed to meet the industrial demand for the training and education of both existing and future engineers in the advanced concepts of sustainable electrical power and energy generation. The aims are to produce graduates of a high calibre with the right skills and knowledge who will be capable of leading teams involved in the operation, control, design, regulation and management of power systems and networks of the future.

The programme aims to:
-Provide you with the ability to critically evaluate methodologies, analytical procedures and research methods.
-Provide an advanced education in electrical power engineering.
-Give you the education, knowledge and the skills you need to make sound decisions in a rapidly changing electricity supply industry.
-Provide a sound understanding of the principles and techniques of electrical power engineering.
-Give a broad knowledge of the issues and problems faced by electrical power engineers.
-Give a solid working knowledge of the techniques used to solve these problems.
-Provide a foundation in power systems principles for graduates with an engineering background.
-Demonstrate the practical relevance of these principles to the operation of successful enterprises in the broad field of electrical power engineering.
-Familiarise professional engineers and graduates with the theory and application of new technologies applied to power systems.

Academic facilities

Students in City's Department of Electronic and Electrical Engineering benefit from a recent lab equipment upgrade worth £130,000. This includes photovoltaic trainers, three phase synchronous machines, AC motor speed control machines, single and three phase transformers, thryistor controllers, a power systems mainframe and power systems virtual instrumentation.

The equipment is essential in training students to be highly skilled professionals in the energy industry.

The photovoltaic trainer, for instance, is a desk-top instrument which teaches the fundamental principles of photovoltaic energy. The 'photovoltaic effect' is a method of energy generation which converts solar radiation into an electrical current using semiconductors arranged into solar cells.

Teaching and learning

Modules are delivered by academics actively involved in energy related research, as well as visiting lecturers from the power industry who provide a valuable insight into the operation of energy companies.

Industry professionals give several seminars throughout the year. At least two industrial trips are organised per academic year.

Modules

The modules for this course are delivered over two semesters, with weekly lessons scheduled over two days a week. The third semester is spent completing a project that involves writing a dissertation and presenting findings. This course is organised into eight modules provided on a weekly basis.

Course content
-Introduction to Power Systems & Energy Management EPM874 (15 credits)
-Systems Modelling EPM744 (15 credits)
-Renewable Energy Fundamentals and Sustainable Energy Technologies EPM879 (15 credits)
-Transmission and Distribution Systems Management EPM875 (15 credits)
-Power Systems Design and Simulation EPM423 (15 credits)
-Power Electronics EPM501 (15 credits)
-Power Systems Protection and Grid Stability EPM990 (15 credits)
-Economics of the Power Industry EPM101 (15 credits)
-Dissertation EPM949 (60 credits)

Career prospects

Graduates are prepared for careers that encompass a variety of roles in the power industry, from technical aspects to management roles. Previously graduates have found jobs as engineers, managers and analysts in the power sector, with companies such as:
-OFGEM
-National Grid
-UK Power Networks
-EON
-EDF
-Vattenfall
-Caterpillar
-Railroad
-Graduates may also wish to further their research in the energy field by considering a PhD

Read less
Discover the real-world career opportunities in the energy sector with this MSc in Energy and Environmental Technology and Economics. Read more
Discover the real-world career opportunities in the energy sector with this MSc in Energy and Environmental Technology and Economics.

Who is it for?

Wherever you are, energy has an implication. This course is for students who want to engage with different types of settings to research and establish the energy, environmental and technological implications that exist within them. Energy and Environmental Technology and Economics students will care for the environment as a sustainable system and ultimately have a desire to improve conditions for the wider population.

Students come from a range of backgrounds including engineering, finance and economics – and from within the energy industry itself.

Objectives

This Masters degree has been designed to give you a wide perspective when it comes to analysing and forecasting the future for energy, environmental technology and economics. We engage with the industry so you gain a real-world understanding of the problems that exist, and we consider our own ethical responsibilities in relation to energy use.

Imagine a Grade 1-listed building such as the Guildhall in London. As an energy consultant your task is to analyse the site to make it more efficient. But there is a caveat: you cannot make any structural changes to the walls or the windows. The MSc Energy and Environmental Technology and Economics course gives you the tools to examine and address these kinds of challenges.

The MSc Energy and Environmental Technology and Economics course is not about learning academic theories. Instead we focus on the breadth of the subject in the real world. By engaging with practising businesses and trade associations we identify a range of perspectives, and look at the influence of a myriad of other forces at play, from regulation and government funding, to behavioural psychology and emerging technologies. Here are some of the questions the course poses:
-Does this new form of technology operate as it should?
-How does the UK relate to other European countries when it comes to energy efficiency?
-How does organisational psychology affect energy use within a company?
-How do you decide which energy contract to choose?
-What is the impact of a consumer society on personal energy use?

Placements

There is no formal requirement to do an industry-based placement as part of the programme. However, some students arrange to undertake their dissertation research within a company or within their part of the world. A recent student investigated the future of coal-fired generation in Turkey, and another student is combining a work placement at The World Energy Council with their dissertation.

Academic facilities

As part of the University of London you can become a member of Senate House Library for free with your student ID card.

Teaching and learning

Teaching is organised into modules comprising four consecutive day courses taken at a rate of one a month or so. This format makes the programme accessible for students who want to study part time while working.

Full-time students are also welcome. Whether you choose to take the course as a part-time or full-time student, we will offer a great deal of support when it comes to helping you prepare for the modules and project work. You will be expected to devote a significant part of your non-taught hours to project work as well as private study.

Our course is led by an exceptional group of experts in energy, supply, demand management and policies. As an example, one of our module leaders leads the UK contribution to writing international energy management standards and informing policy through the European Sector Forum for Energy Management. This forum looks at methodologies across the continent. There is also input to global standards development through the International Standards Organisation (ISO). At City we bring on board people with well-established academic careers as well as leaders from the energy industry. The programme has strong links with industry and commerce and involves many visiting lecturers who hold senior positions in their fields.

The Energy and Environmental Technology and Economics MSc gives you the opportunity to consider the role of International Energy Management Standards. You will explore the opportunities these standards provide for global service users and providers in relation to reducing energy costs and the environmental impact of energy use.

You will discover the range of current European and International Standards, explore why they are needed and how they are developed, and examine the benefits they deliver through case studies.

The UK has had a leading role in developing these standards in terms of both their writing and implementation. For example the Energy Audit standard, which forms part of the EU Energy Efficiency Directive, Article 8, mandates audits for private sector, non-SME organisations. In the UK this has been implemented as the Energy Savings Opportunities Scheme (ESOS).

Modules

Each course module is taught over four consecutive days of teaching with one module each month. Alongside the teaching you will have coursework to complete for each module. The modules run from October to April, and in the remaining time, you will concentrate on your dissertation, which forms a significant part of the programme.

The dissertation gives you the opportunity to create your own questions and to decide on your own area of interest. It should be a detailed investigation into a subject on energy supply and/or demand, with your own analysis and conclusions outlining the way forward. You may see the focus of your dissertation as a future career path, but whatever your area of study, these final few months of the degree should embody your vision of the future.

You will take four core modules and have six elective modules from which you can choose four topics from diverse subjects relating to energy supply and demand. These include energy in industry and the built environment, renewables, energy markets from the purchaser’s perspective and water supply and management. The latter has close parallels, and directly engages, with energy. You start the course with an introduction to energy and environmental issues and energy policies and economic dimensions in the first term, but you do not need to follow the course in any particular order from this point onwards.

If you are interested in sustainability, you have the option of taking up to two elective modules from the MSc in Environmental Strategy offered by the University of Surrey.

Completing eight modules and four examinations and four modular assessments will lead to a Postgraduate Diploma. Completing four core and four elective modules and a dissertation will lead to a Masters degree. If you are interested in this course may also be interested in the MSc Renewable Energy and Power Systems Management.

Core modules
-Introduction to energy and environmental issues (15 credits)
-Energy policies and economic dimensions (15 credits)
-The energy market from the purchaser's perspective (15 credits)
-Corporate energy management (15 credits)

Elective modules
-Energy, consumer goods and the home (15 credits)
-Transport energy and emissions (15 credits)
-Energy in industry and the built environment (15 credits)
-Renewable energy and sustainability (15 credits)
-Risk management (15 credits)
-Water supply and management (15 credits)

Career prospects

The story of energy is now part of public debate and climate change drives the international agenda. In the UK, there are additional energy supply issues, through the decline of existing nuclear capacity, growing imports of fossil fuels and challenging medium-term targets for renewables and low carbon supply.

Our priority is to make you employable in a range of sectors in which effective energy supply and demand side management has become an important consideration.

You will graduate with economic and market-based skills relevant to complying with relevant legislation and technical and engineering skills related to energy generation and management.

With strong industry links and working level experience from our exceptional team of expert lecturers, as well as the diverse modules on offer, you will be equipped to become a leader and entrepreneur in your chosen area of specialisation within the realm of energy management, supply or policy making.

Our graduates have gone on to hold high-ranking positions as energy consultants, data analysts and directors of corporate sustainability working within organisations including:
-AK Home Energy
-Enelco Environmental Technology
-Energy Institute
-Equinoxe Services Ltd
-Log Tech Consultancy
-Ofgem
-Peckham Power
-RWE NPower Renewables
-SCFG

Read less

  • 1
Show 10 15 30 per page



Cookie Policy    X