Mechanical Engineering with a Foundation Year - BEng (Hons)
Currently viewing course to start in 2025/26 Entry.
Our BEng (Hons) Mechanical Engineering will develop you as a skilled engineer capable of undertaking mechanical engineering tasks within and across organisations. The course focuses on the importance of sustainable futures and the Government's STEM agenda, to give you the knowledge and attributes you will need to thrive in this ever-changing industry....
- Level Foundation
- Study mode Full Time
- Award BEng (Hons)
- Start date September 2025
- Fees View course fees
- Subject
- Location City Centre
This course is:
Open to International Students
Overview
In today's fast paced world, technology is advancing at an unprecedented rate. From cutting edge developments in artificial intelligence to sustainable energy solutions, engineering at BCU is the forefront of these innovations. Our campus is situated in the heart of the city, providing you with the perfect environment to immerse yourself in the dynamic field of engineering.
The course is designed to equip you with the skills and knowledge needed to tackle real world challenges. As a BCU engineering student, you'll be positioned to make an impact in various sectors, from civil and automotive to renewable energy and beyond. The demand for skilled engineers has never been higher, and the opportunities are boundless.
Companies are actively seeking graduates with practical skills and critical thinking that is taught on this course. We also have strong ties with industry partners, providing you with invaluable networking opportunities. You'll get to access BCU's cutting edge facilities and also benefit from using the specialist equipment over at the GBS IoT.
This is where your engineering journey begins. Embrace the possibilities and engineer a future that makes a difference.
Our BEng (Hons) Mechanical Engineering will develop you as a skilled engineer capable of undertaking mechanical engineering tasks within and across organisations. The course focuses on the importance of sustainable futures and the Government's STEM agenda, to give you the knowledge and attributes you will need to thrive in this ever-changing industry.
The Foundation Year course option enables you to study for our BEng (Hons) degree over an extended full-time duration of four years by including a Foundation Certificate (year one of four) in your studies. The Foundation Certificate provides a broad study programme that underpins the follow-on degree. In order to progress to the next year of the degree, it is necessary to achieve a pass in all modules of the Foundation Certificate.
What's covered in this course?
Our engineering courses focus on project-based activities, giving you lots of opportunity to work in teams on projects from design to implementation. This will give you practical experience of applying engineering science to real world problems, working in multidisciplinary teams to develop your interpersonal skills, and prepare you for a key aspect of modern engineering practice. Problem-solving and project management are key skills for an engineer, and our focus on practical experience will help to improve your skills in these highly sought-after areas.
During your studies, you will use the latest tools and technologies, developing new skills at an advanced level. The course will encourage your creative thinking and develop your engineering leadership skills. Building on a foundation of the generic skills required by tomorrow’s engineers, you will also explore the wider context of engineering, as well as the application of advanced engineering principles to solve problems through research and development. You’ll engage in independent study and systematic enquiry at an advanced level and take responsibility for the conclusions drawn from it.
You will have lots of opportunity to apply industry-standard modelling and simulation techniques to the analysis, specification and design of mechanical engineering systems so that you are able to apply your knowledge and theory to a practical situation. In this way, we make sure you are ready to step straight into employment.
I decided to study at Birmingham City University because while I was in full time employment this course offered everything that I needed part time and covered all the modules that I needed to progress in my career role. The course offered all the different practical elements as well as the theoretical elements for power generation and design – the subjects that I enjoyed and wanted to progress on to in my career.
Katja Wotton Srbljanin
Why Choose Us?
- Industrial placement year option - Gain desirable employability skills and work experience with the option of an industrial placement year, that will take place between your second and final year of the course.
- Formula Student events at Silverstone - We are one of the select UK universities with access to take part in our international Institution of Mechanical Engineers (IMechE) Formula Student event at Silverstone. Read Marta’s story.
- State-of-the-art facilities - You will be based at our Millennium Point campus in City Centre, where our facilities have undergone a £6.5 million investment with a new maker area, engineering labs/equipment and IT equipment to provide you with the very best learning experience. You will also use our industry-standard equipment and resources, including rapid prototyping, laser-cutting and CNC machining.
- £1.1 million investment in new facilities from the IoT – The Institute of Technology (IoT) has invested in brand-new equipment and facilities, including an Electric Vehicle (EV) Test Rig, an Additive Manufacturing Machine (3D printer) and a material testing-split zone furnace - all industry grade technology that will advance your skills, making you more employable.
- Employable graduates - Our graduates have progressed into roles with leading companies such as Jaguar Land Rover, Morgan Motors, GKN, Bentley, Mercedes, Rolls-Royce and JCB.
Open Days
Join us for an Open Day where you'll be able to learn about this course in detail, chat to students, explore our campus and tour accommodation. Booking isn't open yet for this event, register your interest and we’ll email you as soon as booking goes live.
Next Open Day: 22 March 2025
Entry Requirements
These entry requirements apply for entry in 2025/26.
All required qualifications/grades must have been achieved and evidenced at the earliest opportunity after accepting an offer to help confirm admission and allow for on-time enrolment. This can also include other requirements, like a fee status form and relevant documents. Applicants can track their application and outstanding information requests through their BCU mySRS account.
Essential requirements
80 UCAS Tariff points. Learn more about UCAS Tariff points.
If you have a qualification that is not listed, please contact us.
Fees & How to Apply
UK students
Annual and modular tuition fees shown are applicable to the first year of study. The University reserves the right to increase fees for subsequent years of study in line with increases in inflation (capped at 5%) or to reflect changes in Government funding policies or changes agreed by Parliament. View fees for continuing students.
Award: BEng (Hons)
Starting: Sep 2025
- Mode
- Duration
- Fees
- Full Time
- 4 years
- £9,535 in 2025/26 ✱ Important note for this price
- Apply via UCAS
(↩Back to price) * The Government is proposing to increase the cap on full-time regulated tuition fees to £9,535 for 2025/26 and the University is planning on increasing fees to that maximum level once legislation is enacted. Part-time fees are charged pro-rata, where applicable.
International students
Annual and modular tuition fees shown are applicable to the first year of study. The University reserves the right to increase fees for subsequent years of study in line with increases in inflation (capped at 5%) or to reflect changes in Government funding policies or changes agreed by Parliament. View fees for continuing students.
Award: BEng (Hons)
Starting: Sep 2025
- Mode
- Duration
- Fees
- Full Time
- 4 years
-
TBC
Guidance for UK students
UK students applying for most undergraduate degree courses in the UK will need to apply through UCAS.
The Universities and Colleges Admissions Service (UCAS) is a UK organisation responsible for managing applications to university and college.
Applying through UCAS
- Register with UCAS
- Login to UCAS and complete your details
- Select your course and write a personal statement
- Get a reference
- Pay your application fee and submit your application
Course in Depth
Foundation Year
In order to complete this course you must successfully complete all the following CORE modules (totalling 120 credits):
Mathematics plays a key role in establishing and grounding the professional skills of an engineer. Communicating the ideas of engineering is made both easier and harder by the use of mathematical language.
This module aims to help you become proficient at developing engineering models and arguments, and following them through to their logical conclusions, since application of these arguments has to include their interpretation both to and from the mathematical language.
The module aims to provide you with the knowledge and problem-solving skills in physical science to enable you to progress to the next module in the science theme, Engineering Science 2, and then on to the first year of an engineering degree.
This module aims to provide you with the practical and professional skills to enable you to progress to the next module in the practical theme, Practical Skills II, and then on to the first year of an engineering degree.
The theoretical aspects of physical science and maths are delivered in another theme of the foundation year. The Practical Skills modules sit alongside these and concentrate on the practical aspects to support your learning.
Mathematics plays a key role in establishing and grounding the professional skills of an engineer. Communicating the ideas of engineering is made both easier and harder by the use of mathematical language.
This module aims to help you become proficient at further developing engineering models and arguments, and following them through to their logical conclusions, since application of these arguments has to include their interpretation both to and from the mathematical language.
This module aims to provide the practical and professional skills to enable you to progress to the first year of an engineering degree. As the theoretical aspects of physical science and maths are delivered in another theme of the foundation year, the Practical Skills modules concentrate on the practical aspects.
The module aims to provide you with the knowledge and problem-solving skills in physical science to enable you to progress to the first year of an engineering degree. The science theme contains the material normally encountered in an A level physics course which is relevant to entry to an engineering degree.
First Year
In order to complete this course you must successfully complete all the following CORE modules (totalling 120 credits):
The module aims to provide the underpinning knowledge and problem solving skills in engineering science to enable you to progress to the next module in the theme, Engineering Principles II, and then on to the second year of a range of engineering degrees.
As the practical aspects of engineering science are delivered in another theme of the common first year, the Engineering Principles modules concentrate on the theoretical aspects. The subject material will be delivered in two coherent streams one of which contains predominantly mechanical science and the other contains predominantly electrical science.
The module aims to provide the professional skills needed to enable you to progress to the next stage of the practical theme, onto your next module: Integrated Engineering Project, and then into the second year of an engineering degree.
The subject material will be delivered in two core streams: a PC-based stream, which will include the use of software to support project planning, communication and analysis, and a project-space stream, where you have the opportunity to integrate learning from across all elements of the semester.
You will develop practical professional engineering skills; including skills required for conceiving, designing, implementing and operating (CDIO) engineering solutions.
This module will interact with modules in the other two themes in the first year, relying on the knowledge of mathematical techniques, and the theoretical underpinning of the engineering principles, design and professional skills.
Mathematics plays a key role in establishing and grounding the skills of an engineer, and the ability to communicate the ideas of engineering that are expected of an engineering graduates.
The primary aim of this module is to provide the fundamental mathematical knowledge and techniques needed in order to enable you to use and apply such mathematical techniques for the evaluation, analysis, modelling and solution of realistic engineering problems. Application of these data sets has to include their interpretation both to and from the mathematical language. In addition, this module will introduce students to mathematical modelling software package. This will be used to plot, annotate basic signals and write simple programs to compute mathematical problems.
This module will develop your ability to both work on and communicate engineering realities to a wider audience, at a professional standard.
The module aims to provide the underpinning knowledge and problem solving skills in engineering science to enable you to progress to the second year of a wide range of engineering degrees. As the practical aspects of engineering science are delivered in another theme of the common first year, the Engineering Principles modules concentrate on the theoretical aspects. The subject material will be delivered in two coherent streams one of which contains predominantly mechanical science and the other contains predominantly electrical science.
This module will focus on introducing and building on well-established techniques for mathematically modelling dynamic systems (systems of interest for engineering) for contextualised engineering applications. The module will include an introduction to sophisticated signal analysis technique, Fourier series which is used to transform time-domain signals into their frequency spectra. The module is structured to include a mixture of lectures, tutorials and PC-based laboratories. The lectures will formally introduce material, in tutorials students will work through questions with tutor. The PC laboratories will involve using mathematical modelling software packages to implement mathematical operations.
The module aims to provide the practical and professional skills to enable you to progress on to the second year of an engineering degree. As the theoretical aspects of physical science and maths are delivered in other themes of the first year, the Practical Skills modules concentrate on the practical aspects.
The subject material will be delivered in three coherent streams one of which contains predominantly mechanical and electrical laboratory exercises, a second PC-based stream will include use of software to support project planning, design, communication and analysis and the third, a project space where you have the opportunity to integrate learning from across all elements of the semester.
Second Year
In order to complete this course you must successfully complete all the following CORE modules (totalling 120 credits):
The module aims to provide a basic understanding of thermodynamic and fluid mechanic concepts. The understanding of the transfer of energy within thermodynamic systems and the incurred losses is vital to improve efficiencies of such systems, especially in light of growing environmental concerns and increased economic cost.
The knowledge and understanding will be gained through a balanced mixture of lectures and tutorials, whereby the learning will be supported by experiments.
The module provides you with the opportunity to learn about design, sustainable development, teamwork and communication whilst contributing towards real international development projects.
You will also gain the ability to communicate design ideas and practical details, to evaluate and apply both tangible and subjective feedback, and to conceive, design, implement and operate practical solutions to design opportunities.
It is anticipated that the project vehicle for this module will be the Engineers without Borders Design for People Challenge.
The module introduces the mathematical concepts such as transform calculus and matrix theory used to solve systems of first and second order differential equations underpinning the engineering disciplines undertaken within the Faculty.
This provides you with the capability of modelling systems using both the transfer function and statespace paradigms. In particular, you will be able to model linear systems in continuous and discrete time as well as by frequency response methods.
Teaching and assessment will comprise not only traditional lectures and tutorials but also provide training in industry standard software for problem solving within coursework assessment.
An interdisciplinary module, you will work with students from all fields of engineering to develop skills in engineering leadership and experience creating a purposeful vision and delivering on that vision. This will set the professional skills for business in context by combining your technical course-specific knowledge with professional skills. It is proposed that the vehicle to deliver this will be the biomimicry global design challenge.
The Mechanical Science module applies the principles of engineering, physics, and materials science to the design, analysis, manufacture, and maintenance of mechanical systems and components. It is a branch of engineering that enables you to design, produce, and operate machinery. In keeping with the programme philosophy the module encourages learning through the practical application of fundamental mechanical science principles to the analysis and solution real world problems.
This module develops your research skills, idea generation techniques, and ability to create CAD models and manufactured components.
You will also gain the ability to communicate design ideas and practical details, to evaluate and apply both tangible and subjective feedback, and to conceive, design, implement and operate practical solutions to design opportunities.
Final Year
In order to complete this course you must successfully complete all the following CORE modules (totalling 120 credits):
In the development cycle of new and existing components, processes and systems the use of computer analysis has a strong role to play. Reduced lead times can mean faster arrival at the market than competitors and therefore gaining an advantage. Engineers are at the centre of the development process and therefore require a good understanding of the key aspects of computer aided engineering (CAE).
The module introduces you to the mathematical tools underpinning the analysis, modelling and design of complex vibrating systems and mechanisms as well as the software tools within an appropriate simulation environment used for their solution. Industry standard software will also be used for the design of dynamical control systems using both time and frequency domain techniques.
Teaching and assessment will comprise not only traditional lectures/tutorials, but also use of industry standard software for the purposes of mathematical modelling, all of which are assessed by examination.
Mechanical engineers nowadays solve problems of high and multidisciplinary complexity. Although computational solutions generally lead to reliable results, the engineer should always attempt to validate the findings by alternative methods. This requires a thorough understanding of the underlying problems, but also the approach of reasonable simplification of complex systems without compromising validity.
The dependency of the current economy of fossil fuels as source of power requires a shift in thinking by engineers and companies to design and develop more efficient machines, processes and systems. The module therefore aims to provide you with the knowledge and understanding required to analyse thermodynamic systems concerned with conversion processes between heat and work. In addition the issues and limitations of the energy generation process play also a vital part and how energy can be recovered from processes to improve the overall efficiency.
The module follows the Mechanical Engineering programme philosophy of developing your intellectual and practical competence in the thermodynamic, power generation and energy conversion aspects of mechanical engineering. Formal lectures, tutorials, hands-on experience in labs and solving of problem based scenarios will enhance the learning process.
The purpose of the module is to enable you to undertake a sustained, in-depth and research-informed project exploring an area that is of personal interest to you. In agreement with your supervisor, you will decide upon your topic which will take the form of a practical outcome (artefact) with accompanying contextual material. The main consideration when choosing your topic is that it must be aligned to the programme you are studying, and you should consider the relevance of this topic to your future academic or professional development.
At this level, you will be expected to work independently but you will receive additional one-to-one support from your supervisor, who will be familiar with your chosen topic area. As you progress on the module, extra support will be available and this may take the form of group seminars, workshops and online materials that will help to develop your project.
Download course specification
Download nowEmployability
Through group work and project-based challenges, you will develop transferable and marketable skills and knowledge applicable to a variety of employment opportunities within the mechanical engineering and associated industries.
We will develop the skills, understandings and personal attributes that will help you stand out from the crowd when it comes to securing employment.
We will ensure you are professional, work-ready and enterprising, with a global outlook and the ability to solve problems creatively.
Placements
We aim to have you employer-ready by the time you graduate and as part of this commitment we encourage you to further enhance your career prospects by including an industrial placement in your course.
You will do your placement after the second year of study, which will extend the duration of your course to four years if you are studying on a full-time basis, and you’ll be supported throughout your time away.
Thanks to our excellent partnerships and strong relationships with industry, you could join the ranks of our students who have gained exceptionally high quality work experience at companies including Triumph, BMW and Bosch.
Placements provide the workplace experience that many employers look for and give you an invaluable opportunity to develop your practical expertise, earn money and try out a potential career path.
International
Birmingham City University is a vibrant and multicultural university in the heart of a modern and diverse city. We welcome many international students every year – there are currently students from more than 80 countries among our student community.
The University is conveniently placed, with Birmingham International Airport nearby and first-rate transport connections to London and the rest of the UK.
Our international pages contain a wealth of information for international students who are considering applying to study here, including:
- Details of the entry requirements for our courses
- Some of the good reasons why you should study here
- How to improve your language skills before starting your studies
- Information relevant to applicants from your country
- Where to find financial support for your studies.
Facilities & Staff
Our Facilities
Our state-of-the-art Engineering labs and workshops provide the perfect setting for practical work with modern-day teaching and learning facilities. We pride ourselves on equipping our students with the skill set that they need not only working on industry standard equipment, but having industrial links, which set them up perfectly for a career in engineering.
We have invested in industry-standard facilities to support the practice-based elements of our Engineering courses and give students as much practical learning as possible, to prepare for industry placements and job opportunities after graduation. Students have access to our facilities during classes, and can book out of class sessions with our specialist technicians.
We are a partner of the Greater Birmingham and Solihull Institute of Technology (GBSIoT) and have secured £1.1 million of government funding for investment in brand-new equipment and facilities. Funding of £808,000 from the Department for Education has supported our development of an Electric Vehicle (EV) Test Rig, an Additive Manufacturing Machine (3D printer) and a material testing-split zone furnace.
The IoT has enabled procurement of new technologies for material testing, electronics prototyping and production and 3D scanning to compliment computer aided design for manufacture.
Our staff
Dr Adnan Fazal
Senior Lecturer in Mechanical Engineering
Dr Adnan Fazal is a Lecturer in Mechanical Engineering and Automotive Engineering. His current research interests include pre-stressed fibre reinforced polymers for improved strength, stiffness, impact protection, resistance to crack propagation and protection against abnormal loads. Potential applications of these smart fibre reinforced polymers...
More about AdnanLaura Leyland
Head of the College of Engineering (interim)
Laura Leyland is Interim Head of the College of Engineering and has been innovating in engineering education for over 10 years, teaching materials based modules and practical project focussed delivery with a specific interest in developing humanitarian engineering. This module delivery incorporates the Engineering for People Challenge from...
More about Laura