This course examines the engineeing of Renewable Energy. The technical course equips the student for a wide range of engineering roles.
Study Renewable Energy Engineering at Ulster University in the United Kingdom.
Graduates in Renewable Energy Engineering will provide a body of engineers with the vision and skills necessary to address the design and manufacture of engineering systems and machines aligned to the Renewables Industry. Students entering the course will be given the vision of Renewable Energy Engineering at the initial stage of the programme and will quickly be advised on the aspects in common with the Mechanical and Manufacturing courses.
Innovation and entrepreneurship are important drivers for Renewable Energy Engineering and are embedded within the course, along with ethics, risk and sustainability. Renewable Energy Engineering can be divided into four key sectors i.e. Wind, Water, Biomass and Solar (PV and Heat). These topic areas are all dependent on advances in materials science, computer aided engineering and fundamental science, and the course will focus on these fundamentals while also utilising expertise from the Centre for Sustainable Technologies(CST) for sustainable technology research and advanced materials and manufacture using advanced materials coming from the Nanotechnology and Advanced Materials Research Institute (NAMRI).
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About this course
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This course is the part-time version of the BEng Renewable Energy Engineering degree and offers a flexible learning approach to study.
The duration of the course is in the range of four to seven years, depending on exemption from Level 4 and 5 modules (Years 1 and 2 of equivalent full-time course) and the rate of study.
On average students complete study at half the rate of a full-time student, completing 60 credits out of the 120 credits which make up each year of the equivalent full-time course. The maximum study load is 40 credits per semester.
The course includes modules in mathematics, electrical and mechanical science, materials and manufacturing, computer aided design, electronic circuit design, electrical engineering, industrial management.
Attendance is part-time, day-time and typically requires one full day or two half days per week for 12 teaching weeks each semester. The attendance requirements may vary from semester to semester.
- September 2016
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.
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Mathematics for Engineering
The module covers topics that are suitable for a first year BEng course. These include algebra, trigonometry, matrices, calculus, sequence and series.
Introduction to Renewable Energy
The module provides a firm grounding in energy conversion through fundamental theory demonstrated in the analysis of conventional and alternative energy conversion systems.
Intro to Statics and Dynamics
MEC102 provides the fundamental principles of Statics and Strength of Materials in relation to mechanical engineering and provides a methodology for their practical application. Its content includes:
(a) Basic and derived units, static equilibrium, shear forces, bending moments and friction'
(b) Statically stressed systems both determinate and indeterminate, the theory of torsion and bending.
(c) Those theoretical and practical principles required within each topic area will be developed in lectures and
applied in assignments, tests and tutorials.
d) This module provides an understanding of dynamics, and its application to the solution of engineering problems
A module which integrates formal study with a significant practical programme for the understanding and application of common manufacturing processes. Production of a working electro-mechanical product will deepen knowledge and develop basic skills for selected manufacturing processes. Candidates will critique their work to improve the product design and select appropriate production processes for batch manufacture.
Introduction to Fluid Mechanics and Thermodynamics 1A
This module provides a basic introduction to the principles behind fluid mechanics and thermodynamics. Emphasis is placed on the application of this theory to everyday items, ranging from bicycles to motor cars
This module introduces the student to analogue electronic principles presented using a combination of lectures tutorials and practical laboratories and is assessed by two class tests and a written examination.
Design and Computer Aided Engineering
This module includes freehand sketching, systems of projection, drawing conventions, dimensioning and tolerancing, 3-D digital modelling of parts and assemblies, design documentation, an introduction to the total design activity, formulation of a product design specification (PDS), material selection and manufacturing considerations in design.
Electronics Systems Design
This module introduces the principles of design of analogue and digital building blocks which can be integrated to form electronic systems of moderate complexity. The module also discusses issues related to the interfacing of analogue and digital signals. Both elements of the module are presented through lectures, tutorials and practicals and are assessed using both continuous assessment and formal written examination methods.
Electrical and Energy Engineering
Building on the fundamentals covered in ENE123 (EEE186 Magee), the aim is to develop design skills in the technologies and energy engineering involved with electricity generation, its supply, distribution and end use of electricity, both in a domestic and industrial context.
Turbines are at the heart of renewable energy technologies, forming the energy conversion technology on which wind and most water technologies are based upon. This module introduces the basic physics and engineering technologies, and develops an indepth knowledge of the technologies involved. Environmental issues are discussed and contextualised.
The module provides a general coverage of different classes of materials. Metallic and non-metallic materials are studied with respect to processing, microstructure, mechanical performance under different conditions, applications, cost, the environment and health and safety.
Design and Industrial Applications 2
The module considers creativity in design; product innovation; technical and non-technical aspects of design; safety and product liability; design analysis techniques for economic product manufacture and assembly; functional analysis; value engineering; safety and reliability through design projects; manufacturing processes; assembly techniques; material handling methods; component and product inspection and testing; factory simulation using computer techniques; computer database application for manufacturing management and processing; and design applications using 3-D computer graphics.
Statics and Dynamics 2
MEC 337 provides an extension of the fundamental principles of the Statics and Dynamics of mechanical systems in relation to the analysis and solution of mechanical engineering problems.
Thermal renewable energy technologies are primarily based on combustion or the direct conversion of solar radiation into thermal energy, but also include geothermal heat. They have a wider range opportunities than electrical systems due to the widespread demand for low and medium grade heat and coolth in both industrial and domestic situations. This module introduces the students to these concepts and contextualises the issues.
Computer Aided Engineering (CAE)
This module provides a practical, hands-on treatment of Computer Aided Engineering in the context of application in design practice or manufacturing company. It majors on the more advanced part modelling techniques, assembly modelling, good modelling practice, collaboration and interoperabilty, design documentation, 3D printing, surface modelling rendering, mechanism simulation and Finite Element Analysis. It involves the utilisation of an integrated, state-of-the-art MCAD suite along with the teaching of the general principles of these technologies.
Design and Industrial Applications 3
This module is based on the execution of an industrially generated major design project through multi-disciplinary team activity involving aspects of: project management, market analysis, specification, concept design, budget costing, decision making, detail design, production planning, manufacturing requirements and product costing.
Mechanical Science 3
This module provides adequate technological principles to allow for the solution to practical problems. Those theoretical and practical principles required within both the thermopdynamic and mechanical disciplines will be developed in lectures and applied in assignments, laboratory and tutorials.
Research Studies and Project Management
This module is designed to equip students with the appropriate research and project management skills needed to complete a project within the Computing domain. Firstly, the module provides an underpinning foundation of research concepts, methods and techniques necessary for project development and delivery. Secondly, the different stages of the research process are demonstrated. Thirdly, the students employ skills developed during the module to create a set of project deliverables such as project plan and proposal, critically reviewed literature papers, literature review and project presentation. Embedded in all these activities is the reinforcement of the need for adhering to recognised ethical standards and taking a professional approach to carrying out research.
Final Year Project
Students are required to undertake an individual project during the final year of the course. Its purpose is to provide an experience of developing a software/hardware/engineering solution to a realistic problem. This work combines skills and knowledge acquired previously on the course with those acquired during the project. In particular, students will have an opportunity to (i) strengthen their competence in project management, in taking an initial concept through to a successful implementation; and (ii) enhance their communication skills, in producing a dissertation and defending the work.
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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You will normally be in full-time employment in an engineering capacity regarded as satisfying the industrial training requirements of the equivalent full-time courses. You should have attained a high level of performance in a Higher National Diploma/Higher National Certificate in an appropriate engineering subject, or a Bachelor of Technology degree, or hold an equivalent qualification e.g. Foundation Degree.
You will be required to satisfy the Course Committee that you have the support of your employer for release to attend the courses.
Please check the GCSE requirements below for entry to this course.
GCSE (or equivalent) profile to include minimum of Grade C or above in Mathematics and English Language.
The Faculty of Computing and Engineering does not accept students with Essential Skills in Application of Number as the only mathematics qualification. Please contact the Faculty Office directly on T: 028 90 366305 if you have a query concerning this matter.
English Language Requirements
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.
Teaching and learning assessment
Formal lectures are supplemented by tutorials and laboratory investigations, as appropriate. Practical hands on laboratory sessions are an integral part of many modules throughout all years of the course. Case studies, groupwork and mini-projects are also extensively used. In the final year there is a major individual project.
Generally, a combination of continuous assessment and examination is employed in each module. Continuous assessment includes class tests, library and laboratory based assignments, and individual and group project work. Some modules across all years of the course are continuously assessed.
Exemptions and transferability
Transfer between this course and other similar courses within the Faculty of Computing and Engineering may be possible on the basis of academic performance.
Exemption from parts of the course may be considered based on appropriate performance in a related, designated course or other approved experiential learning (APEL).
The course has been designed to enable students who graduate with a good honours degree to apply for postgraduate study towards a PhD, MSc, MRes or other higher qualification.
Careers & opportunities
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Job prospects in a wide range of engineering industries are excellent with the majority of graduates finding employment within six months of graduation. Graduates with BEng Hons, first class or upper second class award all satisfy the requirements for a wide range of postgraduate research posts and scholarships.
Please contact the Faculty Office directly on T: 028 90 366305 if you have a query concerning this matter.How to apply
- September 2016
For admissions related enquiries please contact the Faculty Office:
T: (028) 9036 6305
Course Director: Dr JP Quinn
Director - Centre for Engineering and Renewable Energy (CERE)
T: +44 28 7167 5461