Bachelor in Renewable Energy Engineering

Last Updated on December 14, 2022

Students in the Bachelor of Renewable Energy (BS) program get the practical skills and knowledge needed to critically evaluate alternative energy sources and deliver practical solutions to energy demand.

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renewable energy engineering requirements

This programme has been designed to provide you with a detailed knowledge of all major renewable energy sources and the engineering skills associated with them, including geothermal, solar, biomass, hydro, marine and wind. In addition, there are courses covering legislative, planning and economic considerations associated with renewable energy, and the integration of renewable energy to the grid.

The course included in this programme cover both the theoretical knowledge and advanced technical skills in demand from this ever-evolving sector. Teaching is by specialist staff drawn from our engineering school as well as from the energy industry, to ensure that students are exposed to the latest developments and future needs of the renewable energy industry.

One of the main features of the programme is its interdisciplinary nature, being suitable for students with mechanical, civil, electrical, chemical and other suitable engineering backgrounds. In special cases, the programme is also open to students with other relevant science backgrounds, including Physics, Chemistry and Applied Maths.

Aberdeen is known as the Energy Capital of Europe and is a major international centre of research and innovation in every aspect of the offshore oil and gas industry. In recent years, however, non-hydrocarbon based energy has grown significantly, mainly due to the large talent pool of energy engineers and scientists based in the Aberdeen region and the abundant wind and tidal energy resources off the Aberdeenshire coast. The city and region is quickly developing as a major hub for renewable energy.

In August 2016, Hywind, the world’s first floating wind farm was installed off the coast of Aberdeenshire by Equinor (formerly Statoil), while in 2018 work commenced on the European Offshore Wind Deployment Centre (EOWDC) in Aberdeen Bay, featuring the world’s most powerful wind turbine.

Entry Requirements for Renewable Energy Engineering

• Typical A-Level Requirements: AAB including A-Level mathematics and a science or engineering subject (physics is preferred)
• International Baccalaureate Requirement: 30-34 points
• Academic Requirement for post-graduation: A good honours degree minimum 2:2 in mathematics, physics or engineering discipline
• English Speaking Requirements: IELTS 6.5 overall with 6.0 in each element

Entry Requirements

Qualifications

The information below is provided as a guide only and does not guarantee entry to the University of Aberdeen.

2:1 (upper second class) UK Honours degree, or an Honours degree from a non-UK institution which is judged by the University to be of equivalent worth in any branch of Engineering, Physics, Maths or Chemistry.

Students with a 2:2 AND 2+ years of relevant experience may also be considered

Key subjects you must have covered: Mathematics.

Academic Technology Approval Scheme (ATAS) certificate

The CAH3 code for this degree is CAH10-01-09. Students who need a visa to live or study in the UK must apply for ATAS clearance. The ATAS clearance certificate must be valid when you apply for a visa to enter the UK. To find out if you need to apply for ATAS clearance, please visit https://www.gov.uk/guidance/academic-technology-approval-scheme.

English Language Requirements

To study for a Postgraduate Taught degree at the University of Aberdeen it is essential that you can speak, understand, read, and write English fluently. The minimum requirements for this degree are as follows:

IELTS Academic:

OVERALL – 6.5 with: Listening – 5.5; Reading – 5.5; Speaking – 5.5; Writing – 6.0

TOEFL iBT:

OVERALL – 90 with: Listening – 17; Reading – 18; Speaking – 20; Writing – 21

PTE Academic:

OVERALL – 62 with: Listening – 59; Reading – 59; Speaking – 59; Writing – 59

Cambridge English B2 First, C1 Advanced, C2 Proficiency:

OVERALL – 176 with: Listening – 162; Reading – 162; Speaking – 162; Writing – 169

Read more about specific English Language requirements here.

Document Requirements

You will be required to supply the following documentation with your application as proof you meet the entry requirements of this degree programme. If you have not yet completed your current programme of study, then you can still apply and you can provide your Degree Certificate at a later date. CVan up-to-date CV/Resumé Degree Certificatea degree certificate showing your qualifications Degree Transcripta full transcript showing all the subjects you studied and the marks you have achieved in your degree(s) (original & official English translation) Personal Statementa detailed personal statement explaining your motivation for this particular programme.

Bachelor In Renewable Energy Engineering

A bachelor’s degree in renewable energy may appeal to students with a keen interest in developing and supporting resources and technologies that expand energy options for economies and societies all over the world.

What exactly is a Bachelor in Renewable Energy? This course of study is a post-secondary degree program that creates and builds upon a foundation of communication, critical analysis, math and science, with a special concentration on renewable resource technologies. These may include green building, biofuels and alternative energy systems such as wind and solar power. Classes may provide a practical knowledge of electrical and mechanical engineering as they apply to renewables, as well as a focus on energy components such as fuel cells and geothermal energy.

This degree may benefit the student seeking to pursue a future in renewable energy by offering an understanding of thermodynamics, energy history, efficient building design, control systems design and more. Graduates may enter a master’s or other advanced degree program with a well-rounded background in renewables, or move directly into the industry.

Tuition and fees for a degree are individually set by each institution. To find out the cost of a course of study, contact directly the admissions office of the program of your choice.

There is a world of opportunity open to students who graduate with a degree in renewable energy. Both the private and the public sectors offer multiple career options. People are needed for project development, component manufacturing, construction, operations and operations managers, installation, education and training, and systems marketing and sales. Graduates may consult for private companies or for public utilities, or secure a government position in civil engineering.

Alternative and renewable energies are being developed and promoted to lessen the impact of finite resources all over the planet. Become a part of this exciting field by beginning a program today. Search for your program below and contact directly the admission office of the school of your choice by filling in the lead form.

Introduction 

Why choose this course?

Our renewable and sustainable engineering degree tackles some of the biggest challenges facing mankind today – affordable energy, climate change, global warming and pollution control.

For students wanting to be at the forefront of new engineering and cost-effective solutions that will help satisfy the need for renewable energy, this degree could be your next step.

Developed by research-active staff with strong professional and academic experience, the course focuses on providing students with the skills and experience needed for careers, working with and developing innovative technologies in a variety of sectors, including renewable energy, sustainable technology, Electrical Engineering, Mechanical Engineering, Construction and many more.

Numerous case studies and field visits throughout the course, give the degree of real-world context. Previous visits have included trips to Electric Mountain (hydro scheme), Sustainable Building Envelope Centre (SBEC), Centre for Alternative Technology (CAT), photovoltaic manufacturing/ research centres and wind, solar, hydro and biomass plants.

You can also choose to study this course as a foundation year BEng (Hons) Renewable and Sustainable Engineering (four years including foundation year) UCAS Code: HH3P

Key course features

• Excellent facilities that include well-equipped computer-aided design laboratories, modern electronics laboratories, specialist manufacturing systems, simulation software, industry-standard instrumentation laboratories, industry specification. Rapid Prototyping facility (fused deposition method) Subsonic wind tunnel laboratory and well-equipped thermo-fluid dynamics lab including a fully operational Pelton wheel and Francis turbine.
• Small class sizes allow for strong tutorial and laboratory experiment support and advice.
• Dedicated maths support for students.
• There are opportunities for industrial visits to local companies, wind farms, biomass plants, Hydro plants and the centre for alternative technology.
• You will have access to industry-standard software packages such as Altium Designer, Multisim, HP VEE, MATLAB & Simulink, Abaqus, AutoCAD, Fluent, Pro-Engineer, SolidWorks.

Entry requirements

BEng (Hons) Renewable and Sustainable Engineering

UCAS Code: HH36

The academic requirements for the course are 112 UCAS tariff points at GCE A-level or equivalent. In addition, passes at GCSE in Maths and English/Welsh (First Language) at grade C/4 or above are normally expected.

Assessment

A broad range of assessment methods are used; these include task-based exercises, oral and poster presentations, essays and laboratory reports, and written exams. Each module is assessed by a variety of methods, enabling students to display their full potential. A project dissertation will form one of the final parts of your assessment.

Career prospects

The course equips you with a thorough knowledge and skills in engineering at the forefront of new and emerging technologies. Graduates will be well placed to become subject specialists within the industry or to pursue research careers within academia.

This programme prepares students for a career in Renewable Energy and Sustainability related work. Please see indeed.co.uk/Renewable-Energy-jobs to get an idea of the current opportunities available.

best university for renewable energy engineering in uk

Renewable energy engineering is developing new means for sustainable energy extraction and designing energy-efficient machinery. Wind, solar, hydrogen fuel cells and bioenergy are considered as the holy grail of sustainable energy. Students will create solutions to problems encountered in renewable energy capture, conversion, storage and management.

Top 10 UK Universities to Study Renewable Energy Engineering

• University of Oxford
• Imperial College London
• University of Edinburgh
• University of Manchester
• Durham University
• University of Exeter
• University of Leeds
• University of Nottingham
• Newcastle University
• University of Aberdeen

University of Leeds – School of Electronics and Electrical Engineering offers undergraduate 4 years integrated Masters MEng in Electronics and Renewable Energy System and postgraduate 12 months MSc (Eng) in Electrical Engineering and Renewable Energy System.

Cranfield University – Centre for Renewable Energy Systems offers 1 year full-time and 2-3 years part-time MSc/PgDip/PgCert in Renewable Energy.

Loughborough University – Centre for Renewable Energy Systems Technology offers three renewable energy related courses such as:

• MSc Renewable Energy Systems Technology – 1 year
• MSc Renewable Energy Systems Technology (Distance Learning) – 2-6 years
• MSc European Master in Renewable Energy – 15 months

University of Nottingham – Department of Architecture and Built Environment offers 12 months MSc/PGDip Renewable Energy and Architecture.

University of Hull – Energy and Environment Institute offers 1 year full-time and 2 years part-time MSc in Renewable Energy.

University of Exeter – College of Engineering, Mathematics and Physical Sciences offer 1 year MSc Renewable Energy Engineering.

These universities provide knowledge about renewable energy and help you develop a successful career in renewable energy.

renewable energy engineering courses uk

Course highlights

• Design renewable energy systems for electricity, transport or heating applications, for residential and commercial markets
• Use cost analysis to compare renewable energy technologies with traditional fuel systems from the points of view of business, industry and maintenance
• Get a better understanding of solar PV, wind turbines, batteries, hydrogen energy, energy-efficient buildings and sustainable transport.
• Learn about many aspects of smart grid management, energy storage, charging of electric vehicles and system automation
• Work in industry on optional modules or your optional placement year, networking with and working alongside established experts and prospective employers

Engineering route compulsory modules

Course content

Compulsory classes

Energy Resources & Policy

Against the background of international commitments on atmospheric emissions, diminishing fossil fuel resources, renewable energy systems deployment and the liberalisation of energy markets, this module examines sustainable options for energy production, supply and consumption. The aim is to give students an understanding of current trends in the energy market, and to enable a critical evaluation of emerging ideas, technologies and policies especially in relation to new and renewable energy supply systems.

Energy Systems Analysis

This module aims to impart an understanding of the underpinning theoretical principles and practical calculation methods for analysis of energy systems and an appreciation of how these systems are integrated in practical applications. Emphasis is on heat transfer and thermodynamic cycles. The underlying principles and analysis methods are appropriate for both renewable and non-renewable energy systems.

Electrical Power Systems

This module provides students with an understanding of the operation of modern electrical power systems featuring renewable and low carbon generation, along with the techniques to undertake a basic technical analysis of key electrical devices and systems.

Energy Modelling & Monitoring

This module provides an understanding of the theoretical and operational principles underlying simulation modelling of energy supply and demand systems and their environmental impact. The emphasis is on practical computer lab-based modelling exercises. It covers detailed energy system simulation, supply-demand matching, energy management and monitoring.

Sustainability

This module provides students with an understanding of the concepts of sustainability and sustainable development. The social, environmental, and economic impact of development strategies will be identified and the mitigation of negative impacts discussed. Topics covered include shifting world views with respect to technology and ecology, green politics, climate change, sustainable development and limits to growth.

Group Project

In this part of the course, projects are offered for selection by groups of typically four individuals. Each project involves the evolution of an energy/environmental system, including a technical appraisal and, where appropriate, an assessment of its cost effectiveness and environmental impact. There will also be site visits to renewable energy system installations.

Generic modules

Select three classes from the following:

Design Management

This module provides a structured introduction to the Design Management process, issues and tools. Topics include Integrated Product Development, and the different approaches and aspects to design development including concurrent engineering, team engineering, product management, design management, distributed design, and decision support. Other topics cover the design activity, team and management organisational structures, key issues concerning design complexity, and design performance and innovation.

Project Management

This module provides students with skills relating to the use of engineering practices in Project Management with particular respect to the effective and efficient use of resources. The syllabus includes an introduction to project management techniques and project control, project networks including critical path analysis, procedural and graphical presentation techniques, an introduction to Contract Law and project budgetary control.

Risk Management

Under Health and Safety legislation, and under the wider European Post-Seveso Directives, it is mandatory for many industries to carry out risk assessments with the aim of showing that risk is As Low As Reasonably Practicable. This module introduces the fundamental techniques of risk analysis and risk-informed decision making. Students will learn the general principles of methods and their place in risk management, as well as the chance to develop skills in applying these methods to variety of engineering examples.

Financial Engineering

This module introduces elements of financial engineering that are applied to reduce risk of business insolvency and enhance the financial robustness of business enterprises. Questions addressed include: What is the best strategy for survival and growth?; What are the options for financing investment projects both in the private and public sectors of an economy?; How would the financial engineer propose to combine loan capital and equity capital to raise funds for an investment initiative; How would he/she advise his/her company/organization to build its investment portfolio to ensure financial security in volatile market conditions?

Environmental Impact Assessment

Environmental impact assessment (EIA) relates to the process of identifying, evaluating and mitigating the biophysical, social, economic, cultural and other relevant effects of development proposals prior to major decision being taken and commitments made.  This module provides students with an introduction to methods used to predict environmental impacts, and to see how these may be used to integrate environmental factors into decisions.

Renewable Energy Technologies 1

Module Leader	Professor Chris Sansom
Aim	An understanding of the principles of renewable energy technologies is key to assimilate the technological basis of the systems and applications. The module provides the fundamentals of the renewable energy technologies and their impact on global and national energy system. The purpose of this module is to introduce the basis for assessment of the performances of solar, wind, wave and tidal, geothermal as well as hydro-electricity technologies.  By the end of the module, you will have a better understanding of the various renewable technologies and will have the opportunity to visit a PV solar plant to see the real dimension of an operational plant.
Syllabus	Photovoltaic technology,Concentrated solar power technology,Onshore and offshore wind energy: fundamentals of wind turbines and placement,Geothermal Systems (including ground-source heat pumps),Wave and tidal energy technologies,Hydro-electricity.
Intended learning outcomes	On successful completion of this module you should be able to:Identify the different components and main configuration of the different renewable technologies covered in the module,Articulate the fundamental principles, terminology and key issues related to the most used renewable energy technologies,Critically compare the challenges for the development and operation of the major technologies, including government regulation and policy,Identify gaps in the knowledge and discuss potential opportunities for further development, including technology and economic potential.

Renewable Energy Technologies 2

Module Leader	Dr Jerry Luo
Aim	This module provides detailed knowledge in energy storage, bioenergy, energy harvesting and energy distribution. This module also provides you with knowledge and experience in designing and analysing renewable energy infrastructures in power generation, energy storage, distribution and corresponding renewable energy applications.
Syllabus	Energy storage materials and technologiesElectrochemical and battery energy storage,Thermal energy storage,Medium to large scale energy storage,Hydrogen storage.BioenergiesBiorefinery,Biofuels,AD technology,Energy from biomass and waste.Energy distributionSmart grid and micro-grid (technical),Smart grid and micro-grid (socio-economic),Smart grid for electric vehicles.Energy harvestingEnergy harvesting technologies,Internet of things (IoT) and energy harvesting for smart energy systems.
Intended learning outcomes	On successful completion of this module you should be able to:Critically evaluate the key benefits and challenges of energy storage, bioenergy, energy harvesting and distribution networks in renewable energy,Identify the appropriate energy storage and distribution methods for different types of renewable energy systems,Analyse the main configurations and components in power generation, energy storage and distribution networks for renewable energy systems,Justify the importance of materials, control, integration and information management issues in renewable energy,Appraise future technology and socio-economic trends in sustainability and assess associated opportunities and challenges.

Engineering Stress Analysis: Theory and Simulations

Aim	This module brings together theoretical and computational stress analysis through finite element simulations, allowing you to appreciate how the two disciplines interact in practice and what their strengths and limitations are. The examination of finite element analysis (FEA) for various practical applications (e.g. engineering components, composite structures, rotating disks, cracked geometries) in conjunction with relevant case studies will allow you to combine theoretical understanding with practical experience, to develop your skills to model and analyse complex engineering problems.
Syllabus	Stress Analysis: introduction to stress analysis of components and structures, ductile and brittle materials, tensile data analysis, material properties, isotropic/kinematic hardening, dynamic strain aging, complex stress and strain, stress and strain transformation, principal stresses, maximum shear stress, Mohr’s circle, constitutive stress-strain equations, fracture and yield criteria, constraint and triaxiality effects, plane stress and plane strain conditions, thin walled cylinder theory, thick walled cylinder theory (Lame equations), compound cylinders, plastic deformation of cylinders, introduction to computational stress analysis,Finite Element Analysis: introduction to FEA, types of elements, integration points, meshing, mesh convergence, visualisation, results interpretation, beam structures under static and dynamic loading, stress concentration in steel and composite plates, tubular assemblies, 2D and 3D modelling of solid structures, axisymmetry and symmetry boundary conditions, CS1: Stress and strain variation in a pressure vessel subjected to different loading conditions, CS2: Prediction and validation of the stress and strain fields ahead of the crack tip. (case studies are indicative).
Intended learning outcomes	On successful completion of this module you should be able to:Develop a strong foundation on stress analysis and demonstrate the ability to analyse a range of structural problems,Explain the fundamentals of Finite Element Analysis, be able to evaluate methodologies applied to the analysis of structural members (beams, plates, shells, struts), and critically evaluate the applicability and limitations of the methods and the ability to make use of original thought and judgement when approaching structural analysis,Provide an in-depth explanation of current practice through case studies of engineering problems,Use the most widely applied commercial finite element software package (ABAQUS) and some of its advanced functionalities,Evaluate the importance of mesh sensitivity in finite element simulations.

Solar Energy Engineering

Module Leader	Dr Peter King
Aim	This module provides detailed knowledge of solar energy generation systems, and their technical specifications. This module provides you with the knowledge and skills to design and critically evaluate solar energy generation systems. An overview of the current state of the art of R&D and the future of solar energy systems will be given.
Syllabus	PV system technologies and materials,PV field design,CSP collector technical specification and design,CSP cooling systems design,CSP power cycles and thermal storage,CSP plant design,CSP mirror durability and soiling,Water use within CSP plants, and its reduction,Software tools for system design and evaluation,Site selection and the socio-economic and environmental impacts,Current R&D activities and future trends.
Intended learning outcomes	On successful completion of this module you should be able to:Critically evaluate the key technologies of solar PV and Concentrating Solar Power (CSP),Select appropriate solutions for the generation of energy using solar PV and CSP for various applications,Select and implement appropriate methods for the design of solar energy systems.

what is renewable energy engineering

Renewable energy engineering is an emerging discipline. Monash Renewable Energy Engineers will cover Wind, Solar, Hydro, Geothermal and Biomass and will focus on identifying and developing sustainable systems for electricity generation. This will include a broad knowledge of renewable energy sources and technologies; ability to assess feasibility of alternative energy options and make recommendations based on site specific resource characteristics.

This course is designed for engineering, maths or science graduates who wish to develop a successful and rewarding career in the renewable energy sector. It will equip you with the multidisciplinary skills required to design, optimise and evaluate the technical and economic viability of renewable energy schemes. The engineering route will provide you with the state-of-the-art technical skills required to design renewable energy systems, including finite element analysis (FEA), computational fluid dynamics (CFD), and technology lifecycle management (TLM). Alternatively, you can specialise in managing renewable energy projects and systems, focusing on topics such as health and safety and environment; energy entrepreneurship and asset management.

The course provides an in-depth knowledge of renewable energy systems design and development, commercial and technical consultancy and project management within the sustainable engineering environment.

You will gain technical skills in and knowledge of solar power, wind power, biofuel and fuel cell technologies, as well as renewable energy business and management. In addition, you will gain practical skills in up-to-date computer-aided simulation technologies such as Polysun for solar energy applications, WindPRO for wind farm applications and ECLIPSE for biomass applications.

Global warming and the consequences of climate change will increasingly affect both developing and developed countries, especially if the greenhouse gases currently increasing carbon dioxide in the atmosphere are not brought to an acceptable level.

A global priority for the 21st century must be to tackle CO2 emissions from fossil fuels, replacing them with sources of energy that are cleaner, sustainable and renewable. According to the International Panel for Climate Change (IPCC), the world’s current use of renewable energy is only 13% of overall energy consumption.

In response to this, European Commission directives set a 20% reduction in the use of fossil fuel in Europe by 2020 and a 15% increase in the use of renewable energy in the UK. This means there are business incentives for developing alternative energy resources and technologies as a substitute for fossil fuel technology.

With the expected global growth in the renewable energy sector, there will be a crucial need for qualified and skilled engineers with specialist knowledge of the relevant technology. This MSc course focuses on viable sustainable and renewable sources of energy conversion based on systems using solar, wind and bio technologies.

Why choose this course?

Climate change is a major challenge for the 21st century, requiring an alternative supply of cleaner energy from renewable sources. This course is designed with an engineering focus that deals with applications, combined with the business element; applicable whether you work for a large organisation or a small-to-medium-size enterprise.

On this course you will gain skills and expert knowledge in solar power, wind power, biofuel and fuel cell technologies, renewable energy business and management. You will use computer-aided simulation technologies such as Polysun for solar-energy applications, WindPRO for wind farm applications and Gabi for life cycle assessment in biomass applications. Through option modules, you will be able to specialise in project engineering and management, risk management or engineering design and development. Advanced topics include 3D solid modelling, computer-aided product development and simulation, and computational fluid dynamics (CFD) analysis and simulation.

Possible careers

In particular some of the roles Renewable Energy engineers may be employed in include:

• contribute to the development and implementation of clean energy policy
• identify sustainable systems for power generation
• understand traditional (hydrocarbon and coal) and alternate renewable power sources and their generation, in order to assess available energy options and optimise the outcome
• provide recommendation and solutions regarding the intersection of traditional power industries and conventional energy sources with renewable energy sources (infrastructure focus)
• manage the process of developing, maintaining and optimising alternative energy assets, and maximising energy usage efficiency.

renewable energy engineering university

Overview

This is an advanced, specialist course in the rapidly expanding area of renewable energy engineering with a clear Mechanical Engineering focus. The course is aimed at students wishing to develop critical understanding of the significant changes afoot in the energy system due to the development and integration of wind, marine, biomass and solar technologies. The course will enable graduates to develop and implement creative solutions to the problems encountered in renewable energy capture, conversion, storage and management.

Students will gain the knowledge and skills to assess renewable energy resources, design appropriate renewable energy systems, evaluate the performance of these systems and assess the wider impacts of renewable energy development. The course provides introductory courses to fundamental energy science and current energy issues, while the project-led courses focus on the design of renewable energy systems. The course concludes with a research-led dissertation in the summer.

Renewable energy research focuses on six main areas:

• Photovoltaics and Solar Energy
• Wind and Marine Energy
• Renewable Energy Systems
• Minimising CO2 Emissions
• Biofuels
• Wind and Marine Energy

The aims of the course are to enable the students to:

• develop detailed knowledge and critical understanding of the core skills in renewable energy resources, converters and systems
• develop and use a significant range of principal and specialist skills, techniques and practices in renewable energy
• be able to apply this knowledge directly to complex applications
• critically review existing practice and develop original and creative solutions to problems within the domain
• communicate and work effectively with peers and academic staff in a variety of tasks, demonstrating appropriate levels of autonomy and responsibility, and
• plan and execute a significant project of research, investigation or development in a specialist area within the renewable energy arena, demonstrating extensive, detailed and critical understanding of that specialism.

Programme duration

• One year (MSc)
• 9 months (Diploma)

Watch videos of the MSc in Renewable Energy Engineering being discussed by:

• Academic Nick Bennett 
• Student Edwin Acosta 
• Student Peter Szabo

September 2022 entry

The deadline for applications from Scottish and RUK students is 31 August 2022. For EU and overseas applicants, we guarantee to consider applications submitted by the 8 August 2022.

The University of Hull is leading the way in renewable energies and low carbon futures through Aura and the Energy and Environment Institute. As the renewable energy sector expands there is huge demand for trained individuals to plan, implement and manage renewable energy projects with 27,000 new jobs expected by 2030.

The Humber is the UK’s ‘Energy Estuary’ and is rapidly becoming the focus of the renewables industry with great opportunities for industrial placements and career prospects – you could hardly choose a better place to study than the University of Hull.

You will gain a good understanding of a range of technologies, such as wind, tidal, solar and hydro-power, through both lectures and hands-on experience in the laboratory. You will develop an understanding of the key research and analytical skills relevant to renewable energy resource analysis, including GIS and industry software, as well as learning key professional skills such as project management, presentations and group work.

There is a strong industrial component, including site visits, guest speakers from industry and the use of ‘real-world’ examples building on the expertise of partners in Aura. The programme is also ideal for students interested in further research in this growth sector with research programmes led by the University’s Energy and Environment Institute.

What you’ll study

The teaching programme is led by the University’s Energy and Environment Institute and runs over two semesters. All modules are compulsory. Each module is worth 20 credits Students take 60 credits in each of the two semesters and then 60 credits for the dissertation.

The Summer Dissertation consists of an individually supervised research project often undertaken in association with local authorities, business or industry.

Core module

All modules are subject to availability and this list may change at any time.

• Dissertation

Compulsory

All modules are subject to availability and this list may change at any time.

• Principles of Renewable Energy
• Research issues in Environmental Management and Renewable Energy
• Environmental and Energy Data Literacy
• Low Carbon Energy Solutions
• Applied Renewable Energy
• Environmental Impact Assessment and Spatial Data

Entry requirements

Normally a Bachelor Honours degree (2.2. or above), or international equivalent, in an engineering or science subject and GCSE Maths or equivalent. If you hold a degree in another subject area, we would still encourage you to apply as we are looking for a real interest and passion for renewable energy and the environment. So we would be happy to consider your application. Similarly, if you do not hold a degree but have relevant professional experience and training, we would welcome your application.