2021/22 Part-time Postgraduate course
Master of Science
Faculty of Computing, Engineering and the Built Environment
Belfast School of Architecture and the Built Environment
Our first term will commence as planned on 21 September and we will be prepared to deliver lectures and other teaching online for Semester One
Some on-campus activities will still take place, based on a robust local risk assessment, and priority will be given to using campus spaces for practice-based learning activities including lab work.
The University’s primary concern remains the physical and mental health, safety and wellbeing of our students, staff, their families and the wider community. Nothing is more important to us.
On our COVID-19 webpages you will find further information for applicants and students, along with answers to some of the questions you may have.
MSc Energy Storage provides the expertise to fulfil the expectations of an energy storage market that is predicted to grow to $250 billion by 2040.
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Energy Storage is a rapidly developing field of study within both academia and industry, in response to the need to decarbonise our energy systems through renewable energy. Bloomberg New Energy Finance predicts explosive growth over the next 12 years.
Our MSc Energy Storage programme will enable graduates to embark on a professional career in energy storage with the high-level skills needed to meet the emerging challenges. Large scale renewable energy from non-dispatchable wind and solar energy, for example, has begun to threaten the operation of existing electricity networks in several countries.
You will be introduced to the essential areas of renewable energy, energy management, distributed energy resource management and energy storage technologies.
A key feature of the course is our staff; you will be taught by published academics who will enhance your learning experience with research-led teaching.
Sign up to register an interest in the course.
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Our MSc in Energy Storage is a three-year part-time Master’s degree designed for those who are keen to address the challenges to move towards a low carbon society.
The progamme provides a thorough grounding in the core disciplines of energy storage and is embedded in global best practice, technology and economics of its deployment. The course combines technology understanding with critical assessment of performance characteristics within energy market structures, giving graduates an expertise in sizing and selecting the optimum energy storage technology.
The course is delivered by the Centre of Sustainable Technologies (CST), whose knowledge, facilities, industrial links and data sets are drawn from more than £10M of externally funded past and current projects in energy storage. As a primary example, SPIRE 2 – Storage Platform for the Integration of Renewable Energy - is a University of Ulster led EU funded Euro 6.7M cross border project exploring how energy storage resources owned by business and domestic consumers can resolve the problem of the variability of output from renewable energy.
Students will have the opportunity to engage with industry during their research dissertation project and through the participation in workshops/seminars organised by the Centre for Sustainable Technologies linked to national and international projects in the field of energy storage and energy.
All modules will be delivered through blended learning (i.e. via virtual learning environment, VLE, as well as traditional face-to-face teaching in Jordanstown campus). Blended learning will provide students with the opportunity to have direct contact with the team, access seminars to engage with industry and generate experience in the laboratories of the Centre for Sustainable Technologies at Jordanstown campus. A blended learning approach will ensure that the learner is engaged and in control of his/her individual learning experience. We also believe that this approach helps to better meet individual needs of the learner.
Teaching methods are diverse and planned for an advanced education in energy storage. Lectures are considered an effective way of engaging students and communicating knowledge coherently. There are both face to face and on-line teaching through our University’s VLE, Blackboard Learn (BBL). Practical, laboratory-based work is a central activity, and the Centre for Sustainable Technologies has a number of state-of-the-art laboratories in which renewable and energy storage systems can be both demonstrated and assessed.
The modules are all 15 credit point modules, except for the dissertation module that is 60 credit points, for a total of 180 credits. Modules are all 100% coursework. There are a maximum of two items of assessment in a module. An item may include more than one component, but the overall item will have a single mark.
The content for each course is summarised on the relevant course page, along with an overview of the modules that make up the course.
Each course is approved by the University and meets the expectations of:
As part of your course induction, you will be provided with details of the organisation and management of the course, including attendance and assessment requirements - usually in the form of a timetable. For full-time courses, the precise timetable for each semester is not confirmed until close to the start date and may be subject to some change in the early weeks as all courses settle into their planned patterns. For part-time courses which require attendance on particular days and times, an expectation of the days and periods of attendance will be included in the letter of offer. A course handbook is also made available.
Courses comprise modules for which the notional effort involved is indicated by its credit rating. Each credit point represents 10 hours of student effort. Undergraduate courses typically contain 10- or 20-credit modules (more usually 20) and postgraduate course typically 15- or 30-credit modules.
The normal study load expectation for an undergraduate full-time course of study in the standard academic year is 120 credit points. This amounts to around 36-42 hours of expected teaching and learning per week, inclusive of attendance requirements for lectures, seminars, tutorials, practical work, fieldwork or other scheduled classes, private study, and assessment. Part-time study load is the same as full-time pro-rata, with each credit point representing 10 hours of student effort.
Postgraduate Master’s courses typically comprise 180 credits, taken in three semesters when studied full-time. A Postgraduate Certificate (PGCert) comprises 60 credits and can usually be completed on a part-time basis in one year. A 120-credit Postgraduate Diploma (PGDip) can usually be completed on a part-time basis in two years.
Class contact times vary by course and type of module. Typically, for a module predominantly delivered through lectures you can expect at least 3 contact hours per week (lectures/seminars/tutorials). Laboratory classes often require a greater intensity of attendance in blocks. Some modules may combine lecture and laboratory. The precise model will depend on the course you apply for and may be subject to change from year to year for quality or enhancement reasons. Prospective students will be consulted about any significant changes.
Assessment methods vary and are defined explicitly in each module. Assessment can be a combination of examination and coursework but may also be only one of these methods. Assessment is designed to assess your achievement of the module’s stated learning outcomes. You can expect to receive timely feedback on all coursework assessment. The precise assessment will depend on the module and may be subject to change from year to year for quality or enhancement reasons. You will be consulted about any significant changes.
Coursework can take many forms, for example: essay, report, seminar paper, test, presentation, dissertation, design, artefacts, portfolio, journal, group work. The precise form and combination of assessment will depend on the course you apply for and the module. Details will be made available in advance through induction, the course handbook, the module specification and the assessment timetable. The details are subject to change from year to year for quality or enhancement reasons. You will be consulted about any significant changes.
Normally, a module will have 4 learning outcomes, and no more than 2 items of assessment. An item of assessment can comprise more than one task. The notional workload and the equivalence across types of assessment is standardised.
Calculation of the Final Award
The class of Honours awarded in Bachelor’s degrees is usually determined by calculation of an aggregate mark based on performance across the modules at Levels 5 and 6, (which correspond to the second and third year of full-time attendance).
Level 6 modules contribute 70% of the aggregate mark and Level 5 contributes 30% to the calculation of the class of the award. Classification of integrated Master’s degrees with Honours include a Level 7 component. The calculation in this case is: 50% Level 7, 30% Level 6, 20% Level 5. At least half the Level 5 modules must be studied at the University for Level 5 to be included in the calculation of the class.
All other qualifications have an overall grade determined by results in modules from the final level of study. In Master’s degrees of more than 200 credit points the final 120 points usually determine the overall grading.
The University employs over 1,000 suitably qualified and experienced academic staff - 59% have PhDs in their subject field and many have professional body recognition.
Courses are taught by staff who are Professors (25%), Readers, Senior Lecturers (18%) or Lecturers (57%).
We require most academic staff to be qualified to teach in higher education: 82% hold either Postgraduate Certificates in Higher Education Practice or higher. Most academic staff (81%) are accredited fellows of the Higher Education Academy (HEA) - the university sector professional body for teaching and learning. Many academic and technical staff hold other professional body designations related to their subject or scholarly practice.
The profiles of many academic staff can be found on the University’s departmental websites and give a detailed insight into the range of staffing and expertise. The precise staffing for a course will depend on the department(s) involved and the availability and management of staff. This is subject to change annually and is confirmed in the timetable issued at the start of the course.
Occasionally, teaching may be supplemented by suitably qualified part-time staff (usually qualified researchers) and specialist guest lecturers. In these cases, all staff are inducted, mostly through our staff development programme ‘First Steps to Teaching’. In some cases, usually for provision in one of our out-centres, Recognised University Teachers are involved, supported by the University in suitable professional development for teaching.
Figures correct for academic year 2019-2020.
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Here is a guide to the subjects studied on this course.
Courses are continually reviewed to take advantage of new teaching approaches and developments in research, industry and the professions. Please be aware that modules may change for your year of entry. The exact modules available and their order may vary depending on course updates, staff availability, timetabling and student demand. Please contact the course team for the most up to date module list.
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The aims of the module are to understand through a series of lectures and seminars, the technologies that enable direct or indirect electricity storage. Such systems in a global context are at a range of scales and are dependent on local geographical, environmental, infrastructural and economic factors. The understanding of the role of electrical storage technologies in storing and managing both electricity supplies and demands
This module examines current and future energy markets, market participation, the development of the smart grid and how building-integrated storage and generation can be used to optimise profit and energy efficiency.
Energy resources, energy production, energy economics and the environment are all inextricably linked. These ties need to be enforced if the concept of sustainability is to be realised.
This module will introduce students to wind energy theory and technology, resource assessment and wind farm site development. It will also discuss the implications of both very large scale development and large numbers of individual turbines on existing electricity distribution networks.
This module will provide the participant with a global overview of best practice that demonstrates the successful integration of Renewable Energy in both the electricity Transmission System and the electricity Distribution System. Furthermore, it will address in detail heating, cooling and alternative distributed energy resource applications in a global context.
This module will provide the participant with a global overview of best practice that demonstrates the successful integration of Renewable Energy in both the electricity Transmission System to the electricity Distribution System. Furthermore, it will address in detail heating, cooling and alternative distributed energy resource applications in a global context.
The aims of the module are to understand through a series of lectures and seminars, the array of techniques and technologies associated with demand side management and how its role in variable renewable energy management has evolved into consideration as distributed energy resources (DER). DER will be demonstrated in laboratories and assessment will be through a series of design problems to test your mastery of this specialist area.
This module will enable students to appreciate, analyse and evaluate current solar energy technologies and understand how these resources may be managed with a view to future sustainability and demonstrate how the management of energy can benefit industry financially in the short term and influence sustainability in the longer term.
This module will allow the student to undertake an independent, in-depth study of a particular aspect of renewable energy technology or energy mnagement strategy, policy or implementation whether covered in the course or not. It will provide an opportunity for students to integrate knowledge in the identification, description analysis and, where appropriate, solution of a problem within the area of Renewable Energy and Energy Management, and to place it within the context of existing knowledge and recent developments in this area.
We recognise a range of qualifications for admission to our courses. In addition to the specific entry conditions for this course you must also meet the University’s General Entrance Requirements.
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(a) have gained:
(i) a second class honours degree or better, in the subject areas of science or engineering or related discipline, from a university of the United Kingdom or the Republic of Ireland, or from a recognised national awarding body, or from an institution of another country which has been recognised as being of an equivalent standard;
(ii) an equivalent standard (normally 50%) in a Graduate Diploma, Graduate Certificate, Postgraduate Certificate or Postgraduate Diploma or an approved alternative qualification; and the qualification must be in the subject areas of science, engineering or related discipline.
(b) provide evidence of competence in written and spoken English (GCSE grade C or equivalent).
In exceptional circumstances, as an alternative to (a) (i) or (a) (ii) and/or (b), where an individual has substantial and significant experiential learning, a portfolio of written evidence demonstrating the meeting of graduate qualities (including subject-specific outcomes, as determined by the Course Committee) may be considered as an alternative entrance route. Evidence used to demonstrate graduate qualities may not be used for exemption against modules within the programme.
English language requirements for international applicants
The minimum requirement for this course is Academic IELTS 6.0 with no band score less than 5.5. Trinity ISE: Pass at level III also meets this requirement for Tier 4 visa purposes.
Ulster recognises a number of other English language tests and comparable IELTS equivalent scores.
Students may be admitted to the programme in line with Accreditation of Prior Learning guidelines. Students from this course would be eligible to directly enter graduate employment or to proceed to further study at PhD level.
Typically we require applicant for taught programmes to hold the equivalent of a UK first degree (usually in a relevant subject area). Please refer to the specific entry requirements for your chosen course of study as outlined in the online prospectus. We consider students who have good grades in the following:
Typically, we require applicants for taught programmes to hold the equivalent of a UK first degree.
Please refer to the specific entry requirements for your chosen course of study as outlined in the online prospectus.
The comparable US qualifications are as follows:
UK 2:1 Degree - Bachelor degree with a cumulative GPA of 3.0 out of 4
UK 2:2 Degree - Bachelor degree with a cumulative GPA of 2.6 out of 4
|Level 12 English Lang in HSD|
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The MSc Energy Storage programme aims to prepare students for a successful career in energy or energy storage. In the United States, it is predicted that there will be over 350,000 energy storage jobs by 2025. The EU will support a new battery cell manufacturing industry with a 200M Euro investment. The UK Clean Growth Strategy reports over 430,000 in the low carbon sector and 17,750 jobs linked with the growing energy storage and electric vehicle industry.
Students will have the opportunity to apply for a job or improving their position in energy transmission companies, energy distribution companies, energy supply companies, consultancies and at a regional or national government level.
Furthermore, employability is at the heart of Ulster University vision. The MSc Energy Storage programme will allow students to develop and enhance their employability skills. Employability is embedded within the modules rather than concentrating on specific modules.