Skip to main content

Visit to apply

Civil Engineering BEng

Key Information

Course code

H208

H209 with placement

Start date

September

Placement available

Mode of study

3 years full-time

4 years full-time with placement

Fees

2024/25

UK £9,250

International £23,615

Scroll to #fees

Entry requirements

2024/5

AAB - BBB (A-level)

DDD (BTEC)

30 (IB)

Scroll to #entryRequirements

Overview

Ranked top five in London for Civil Engineering by the Complete University Guide 2024.

Are you looking for a rewarding and challenging career? Civil engineering can offer you a career that can literally change the world. Civil engineers design, construct, and maintain features of the natural and the built environment, skills that help solve the problems communities face today, and prepare for those that will confront us in the future.

Inspired by these challenges, Brunel has designed its Civil Engineering BEng programme. It will engage your creative spirit and support your development as an effective learner, while equipping you with the skills needed to thrive in multidisciplinary engineering team environments. Throughout your degree you will study in a range of sector-leading labs and be taught by a unique team of highly experienced civil engineering academics from across the globe.

After a broad-based first year studying a range of engineering disciplines, in Year 2 we focus on core knowledge of civil engineering, such as material science, structural analysis, hydraulics and surveying. In your final year you can either stay on the main civil engineering programme, or choose one of our two specialist pathways in environmental engineering or flood and coastal engineering.

Between your second and third years you can undertake a placement year – a great opportunity to prepare yourself for the world of work. You could find yourself working in an office, design projects, or working outdoors, on construction sites. We highly recommend taking a placement as it can improve your prospects of getting the job you most desire after graduating.

At the end their final year, engineering and maths students are invited to showcase their project work at Brunel Engineers +, an event that both celebrates their achievements and gives them the chance to network with industry figures and employers. This video shows some of the projects exhibited at the 2024 Brunel Engineers + event, with explanations by the students themselves.

Course content

Year 1
Brunel’s unique Common Year 1 syllabus is taken by all engineering students at the University. Studying alongside mechanical, electrical, aerospace and chemical engineering students, you’ll learn about the fundamental principles that underpin all engineering.

Year 2
The focus moves to the core civil engineering subjects of surveying, material science and analysis, structural mechanics, fluid and soil mechanics. After Year 2 you can opt to undertake a year-long placement.

Year 3
Your knowledge of core civil engineering subject areas develops further, encompassing computational analysis techniques, structural analysis and design, geotechnical engineering, project and infrastructure management.

Compulsory

  • Engineering Mathematics and Programming I

    Aims: To develop students’ ability to understand and apply fundamental methods of engineering mathematics; to introduce the use of programming in engineering, and develop students’ ability to represent and solve problems algorithmically.

  • Engineering Mathematics and Programming II

    Aims:  To develop students’ ability to understand and apply fundamental methods of engineering  tmathematics;o introduce the use of programming in engineering, and develop students’ ability to represent and solve problems algorithmically.

  • Engineering Practice

    Aims: To develop the skills required by students studying in all engineering disciplines, thereby supporting their journey through Higher Education and into their professional life with the intention of maximising their employability. Skills development in the following areas will be addressed: problem solving; personal development; professional development; career planning; basic engineering design; introductory project management; communication; working in inclusive teams; health and safety; security.

  • Engineering Systems and Energy 1

    Aims: To provide a grounding in concepts of measurement and uncertainty; to provide knowledge about applied physics relations that govern engineering systems within their boundaries and via their variables of interaction; to establish ability to define system boundaries and apply relevant simple models.

  • Engineering Systems and Energy 2

    Aims: To provide a grounding in concepts of measurement and uncertainty; to provide knowledge about applied physics relations that govern engineering systems within their boundaries and via their variables of interaction; to establish ability to define system boundaries and apply relevant simple models.

  • Engineering Mechanics - Statics

    Aims: To provide a grounding in the fundamental principles of engineering mechanics; to provide knowledge and understanding of Newton’s laws and their application for the solution of static problems; to provide experience and confidence in problem-solving.

  • Engineering Mechanics and Materials

    Aims: To provide a grounding in the fundamental principles of engineering mechanics, including statics and dynamics; to provide knowledge and understanding of the common and important material properties for various engineering applications; to provide experience and confidence in problem-solving.

  • Civil Engineering Principles and Practice

    Aims: To develop understanding of the contemporary civil engineering profession and what being a Chartered Civil Engineer involves (focusing on the pathways and attributes, e.g. project management, health and safety, sustainability, communication, responsibility and independent judgement) and principles of ethics; to develop fundamental skills in conceptual civil engineering design (practical problem solving, technical drawing through sketching, group project work, and communication); to integrate civil engineering design with sustainable development based on circular economy design, environmental management and societal needs, climate change adaptation and mitigation, renewable energy, and Industry 4.0, principally in the context of SDG 11 (Sustainable Cities and Communities).

Compulsory

  • Civil Engineering Toolbox and Surveying

    Aims:  To enable students to develop technical skills linked to civil engineering design and construction; to introduce students to the principles and methods of collecting, processing and ethical use of spatial data (including surveying for gathering engineering information and transferring a design to a construction site); to enable students to develop practical skills through conducting surveying activities such as setting out, use of levels and theodolites and calculation procedures and applying GIS tools for modelling and analysis of geospatial data in design, construction, and maintenance of civil engineering infrastructure.

  • Construction Material and Sustainability

    This module aims to give students deeper understanding on construction materials design and applications, including their strength and limitations. It will support students application of sustainability in engineering construction.

  • Design Project

    Aims:  To develop conceptual design solutions for an engineering task from professional engineering perspective; to outline stages of project development together with client/stakeholder needs, state of the art, codes of practice, health and safety, sustainability, climate change impact and ethics; to assess sustainability issues from environmental, societal and economic perspectives and evaluate CO2 emissions for the whole-life cycle of the proposed designs, in the context of the Sustainable Development Goals (SDGs); to improve team working and communication skills through group work and presentations.

  • Fluid Mechanics and Hydraulics

    Aims:  To deepen students’ understanding of engineering fluid mechanics, hydraulics and hydrological processes; to enable students to apply these concepts to relevant engineering systems, in particular, flow in pipes; flow in open channels; hydraulic structures; coastal structures, energy dissipation and runoff flow estimation; to increase students’ understanding of flow generation and risks of flooding (land and coastal flooding).

  • Reinforced Concrete Design

    Aims: To develop students’ understanding of the principles of structural design and iterative design process; to enable students to apply the principles of structural design for concrete conforming to the current codes of practice and produce details of structural elements; to develop students’ knowledge and understanding of appreciation of complexity of structural problems, the limitation of analytical techniques for structural problems, and the needs of a holistic approach to consider a range of factors to reach design solutions.

  • Soil Mechanics

    Aims:  To cover the fundamental multi-phase nature of soil; the effective stress concept, consolidation problems; to develop students’ understanding of the basic principles of soil mechanics – how soil behaviours when subject to engineering loads and construction processes; to develop students’ basic knowledge in engineering design of geotechnical system.

  • Structural Analysis

    This module aims to enable students develop further their ability to analyse structures including statically indeterminate structures and learn the fundamental principles and the main tools for the analysis of solid body mechanics.

  • Engineering Mechanics and Materials II

    Aims:  To provide students with a qualitative understanding of different types of internal actions (stresses and strains), in structural members associated with different external loads; to enable students to determine the profile of elastic stresses and strains in structural members, establish relationships between complex states of stresses and strains, determine critical stresses and strains and check them against failure criteria; to provide students with knowledge of instability in structural elements subject to compressive load and determining the critical load.

Compulsory

  • Resilient Infrastructure and Transport

    Aims: To develop understanding of infrastructure systems with a focus on how climate change and other global challenges affect sustainable infrastructure development; to introduce contemporary transport planning with a focus on inclusive urban street design and highway management; to introduce novel concepts on resilience-based design and assessment of critical infrastructure exposed to different stressors; to develop knowledge and understanding of different approaches to improve and adapt infrastructure systems, such as transport networks, recognising contributions to development goals including SDG 9 (Industry, Innovation and Infrastructure), SDG 11 (Sustainable Cities and Communities), SDG 13 (Climate Action).

  • Project Planning, Procurement and Risk

    Aims:  To provide knowledge and awareness of project feasibility, management theory, construction procurement, risk management and project planning; to provide the know-how and confidence in the application of management procedures for the delivery of civil engineering projects; to develop understanding of how effective project management contributes to sustainable development, such as by using SDG indicators measurable at project level, notably SDG 8 (Decent Work & Economic Growth) and SDG 12 (Responsible Consumption & Production).

  • Computational Structural Analysis

    Aims: To develop students’ knowledge and understanding of how structures and structural elements respond to loading actions; to enable students to conduct different methods of structural analysis including elastic and inelastic analysis methods, and to develop the ability to choose the appropriate models and methods for different structural scenarios; to develop the ability of the students to understand and apply concepts and theories of structural analysis to design and to verify the structural response using conceptual design, approximate analysis and numerical methods, especially in the context of SDG9 (Industry, Innovation and Infrastructure); to develop students’ competencies in using computational analysis methods for structural analysis.

  • Design of Steel and Timber Structures

    Aims:  To further develop students’ understanding, and application, of the key principles of limit state design; to introduce students to the principles of preliminary design and structural analysis of structural steelwork; to develop students understanding of how forces are transmitted through a structure, and the consequences for analysis and design; to introduce students to the principles of buckling in steel beams and columns; to consider the design implications for rehabilitation and refurbishment of existing steel buildings; to introduce students to the key principles and activities for the design of timber structures to Eurocode 5. This includes understanding the orthotropic nature of timber, the joint behaviour and the design of beams; to develop students' understanding of the consequences of design choices on the associated environmental impact, and introduce methods of accounting for these impacts, with recognition of contributions to SDG 11 (Sustainable Cities and Communities), SDG 12 (Responsible Consumption and Production), and SDG 13 (Climate Action).

  • Geotechnical Engineering

    This module aims to develop students’ understanding of the basic principles of seepage, consolidation and shear strength of soils. It will introduce students to rock mass strength, slope stability, bearing capacity and foundations.

  • Integrated design project

    Aims:  To enable students to apply civil engineering concepts and tools to analyse, model and solve problems; to help students to demonstrate a comprehensive knowledge and understanding of projects, including financial and business management; to foster students to develop creative and innovative civil engineering solutions, recognising contributions to SDG 8 (Decent Work and Economic Growth), SDG 9 (Industry, Innovation and Infrastructure), SDG 11 (Sustainable Cities and Communities), and SDG 12 (Responsible Consumption and Production).

  • Final Year Individual Project

    Aims: To give experience in the planning and conducting a major civil engineering project; to consider the wider implications of the research, including those related to health and safety, sustainability, equality, diversity and inclusion and also the environment and economy, align with SDG4 (Quality education) and SDG5 (Gender equality); to exercise application of analytical, numerical and/or experimental methods in the analysis of a civil engineering problem; to review the results, develop self-direction in finding solutions and draw conclusions; to prepare a professional-standard technical report, with appropriate references and context provided, as well as critical analysis and conclusions; to apply and improve transferable skills; to give due consideration to research ethics.


This course can be studied undefined undefined, starting in undefined.

This course has a placement option. Find out more about work placements available.


Please note that all modules are subject to change.

Careers and your future

Graduates of our Civil Engineering BEng degree are able to:

  • address the needs of society, business and the environment
  • deploy appropriate engineering methods and technologies
  • solve complex engineering challenges
  • work with the environment in a sustainable manner to mitigating climate change impact on infrastructure and human society

This degree is accredited by the Joint Board of Moderators (JBM), comprising the Institution of Civil Engineers, Institution of Structural Engineers, Institute of Highway Engineers, the Chartered Institution of Highways and Transportation and the Permanent Way Institution on behalf of the Engineering Council as fully meeting the educational base required for an Incorporated Engineer (IEng) and partially meeting educational base required for a Chartered Engineer (CEng).

UK entry requirements

2024/25 entry

  • GCE A-level AAB-BBB including Maths and  one of the following subjects; Physics, Chemistry, Biology, Geography, Geology, Environmental Science, Environment Studies, Computer Science, Electronics or Design and Technology (Use of Maths and General Studies not accepted).
  • BTEC Level 3 Extended Diploma (QCF) DDD in Engineering, Mechanical Engineering, Manufacturing Engineering, Electrical/Electronic Engineering, with Distinctions in Further Mathematics for Technicians and Further Mechanical or Further Electronic/Electrical Principles modules.
  • BTEC Level 3 National Extended Diploma (RQF) DDD in Engineering, Mechanical Engineering, Manufacturing Engineering, Electrical/Electronic Engineering, with Distinctions in Engineering Principles and Calculus to Solve Engineering Problems.
  • BTEC Level 3 Diploma (QCF)/BTEC Level 3 National Diploma (RQF) DD in Engineering, Mechanical Engineering, Manufacturing Engineering, Electrical/Electronic Engineering, with Distinction in Further Mechanical or Further Electrical Principles (QCF); Engineering Principles & Calculus to Solve Engineering Problems (RQF), AND A-Level Maths at grade B (Use of Maths not accepted).
  • BTEC Level 3 Subsidiary Diploma (QCF)/BTEC Level 3 National Extended Certificate (RQF) D in Engineering, Mechanical Engineering, Manufacturing Engineering, Electrical/Electronic Engineering, with A-Levels grades BB to include Grade B in Maths and Grade B in one of the following subjects; Physics, Chemistry, Biology, Geography, Geology, Environmental Science, Environment Studies, Computer Science, Electronics or Design and Technology (Use of Maths and General Studies not accepted).
  • International Baccalaureate Diploma 30 points, including 5 in Higher Level Maths and Higher Level 5 in one of the following subjects; Physics, Chemistry, Biology, Computer Science, Geography, or Design Technology. GCSE English equivalent SL 5 or HL 4 and Mathematics SL 4 or HL 4.
  • Obtain a minimum of 120 UCAS tariff points in the Access to HE Diploma in Engineering with 45 credits at Level 3. All Maths and Science units must be Distinctions at level 3.
  • T levels : For subjects accepted and grade requirements please contact the admissions office.

Five GCSEs to include grade C or grade 4 in English Language and Maths.

Please check our Admissions pages for more information on other factors we use to assess applicants as well as our full GCSE requirements and accepted equivalencies in place of GCSEs.

Brunel University London is committed to raising the aspirations of our applicants and students. We will fully review your UCAS application and, where we’re able to offer a place, this will be personalised to you based on your application and education journey.

If you are unable to meet the direct entry criteria above, you are invited to apply for a foundation course in Engineering at Brunel Pathway College. When you successfully pass the foundation year, you can progress on to the Civil Engineering BEng.

EU and International entry requirements

English language requirements

  • IELTS: 6 (min 5.5 in all areas)
  • Pearson: 59 (59 in all sub scores)
  • BrunELT: 58% (min 55% in all areas)
  • TOEFL: 77 (min R18, L17, S20, W17) 

You can find out more about the qualifications we accept on our English Language Requirements page.

Should you wish to take a pre-sessional English course to improve your English prior to starting your degree course, you must sit the test at an approved SELT provider for the same reason. We offer our own BrunELT English test and have pre-sessional English language courses for students who do not meet requirements or who wish to improve their English. You can find out more information on English courses and test options through our Brunel Language Centre.

Please check our Admissions pages for more information on other factors we use to assess applicants. This information is for guidance only and each application is assessed on a case-by-case basis. Entry requirements are subject to review, and may change.

Fees and funding

2024/25 entry

UK

£9,250 full-time

£1,385 placement year

International

£23,615 full-time

£1,385 placement year

Fees quoted are per year and may be subject to an annual increase. Home undergraduate student fees are regulated and are currently capped at £9,250 per year; any changes will be subject to changes in government policy. International fees will increase annually, by no more than 5% or RPI (Retail Price Index), whichever is the greater.

More information on any additional course-related costs.

See our fees and funding page for full details of undergraduate scholarships available to Brunel applicants.

Please refer to the scholarships pages to view discounts available to eligible EU undergraduate applicants.

Scholarships and bursaries

Teaching and learning

Lectures

Lectures will be delivered using a variety of different methods. Some will be delivered live online or in-person on-campus, while others will be pre-recorded and made available online for you to access prior to engaging in interactive in-person tutorials or seminars on campus. Some on-campus live lectures will be simultaneously live streamed; all live lectures, whether delivered online or on-campus, will be recorded and made available for you to review after each lecture has taken place.

Tutorials

All lecture-based modules will be supported by regular (in most cases, weekly) tutorials or seminars that will all be held on campus, allowing you to work with both staff and other students on the practical application of what has been discussed during lectures.

Laboratory classes

Laboratory classes will be held on campus. Students will have the opportunity to perform experiments and carry out other hands-on practical activities in the engineering labs and workshop spaces. Small group project work will also be carried out in person on campus, supported by regular on-campus interactive discussion sessions (workshops). You'll need to come onto campus on most days to participate in all the teaching activities that make up the Engineering Year 1.

The University’s online digital assessment platform will be used for the submission of written course work. All examinations will take place in person on campus. Other forms of assessment, such as presentations, are also expected to be run on campus.

Assessments

These will be run using a variety of formats, including on-campus in-person exams, on-campus presentations, and written reports with on-line submission. On-line presentation might be used in instances where this would be deemed appropriate.

Access to a laptop or desktop PC is required for joining online activities, completing coursework and digital exams, and a minimum specification can be found here.

We have computers available across campus for your use and laptop loan schemes to support you through your studies. You can find out more here.

Our civil engineering degrees are delivered by a diverse team of academic staff. This means you’ll be learning from a teaching team with both scientific knowledge and industrial experience. There will also be guest lectures from our industry partners and civil engineering site visits.

Study will combine lectures, tutorials and seminars, laboratory work, computer modelling, field work, self-study, research reports and project work.

Should you need any non-academic support during your time at Brunel, the Student Support and Welfare Team are here to help.

 

Assessment and feedback

Your progress will be assessed via assignments, presentations, technical and laboratory reports, exams and the final year major research project.