Course structure
Year 1 core modules
Electrical Principles (AC/DC)
This module will introduce you to the fundamentals of electrical circuit theory and how to apply it to analyse simple electric circuits. The module will also introduce you to electromagnetic energy conversion and AC power.
The module is taught with lectures, seminars and related practical work. Your lectures will provide an explanation of principles and discussion of applications. Practical sessions will provide you an opportunity to develop practical skills through the use of laboratory setups that reinforce the lecture material.
Engineering Mathematics
This module introduces the range of mathematical skills that are relevant to an engineering degree. You revisit and develop your knowledge of the fundamentals of algebra, trigonometry and basic statistics. The central ideas of vectors, matrices, complex numbers, and differential and integral calculus are also examined.
Throughout the module you develop a range of mathematical skills and techniques fundamental to the solution of engineering problems. You also advance your skills in selecting and applying mathematical techniques.
This module is delivered through a combination of lectures and tutorial sessions.
Materials and Sustainability
You look at engineering materials in lab-based practical sessions. Fundamental relationships between processing, structure, properties and performance are explored to highlight factors which influence the suitability of materials for various engineering applications.
Mechanical Engineering Practice
You develop and enhance the practical, professional and mechanical engineering skills necessary for success in both the academic and work environment. This practically-focused module enables you to develop your knowledge, confidence and practical skills. You also look at creating an engineered design and the organisational issues of controlling a project.
Structural Mechanics
This module introduces common types of structure used in engineering, assesses the types of loads they must resist and provides you with the analytical skills necessary to design the components that make up the structure.
Specific areas of study include: basic concepts of force, stress and strain; properties of materials and sections; analysis of frames, beams and columns; equilibrium conditions and statical determinacy; beam bending movement, shear force and deflection; and lightweight cables.
Lectures will introduce each major topic on the module with tutorials used to practise calculations. Laboratory practicals are used to investigate the properties of construction materials and develop a deeper understanding of structural theory.
The module is assessed by in-course assignment and an examination, comprising calculations and short answer questions on the module indicative content.
Thermofluids
This module introduces the student to the basic principles of fluid mechanics, properties of fluids, hydrostatics, continuity equation, Bernoulli's equation, flow measurements, real flow in pipes, friction losses and momentum equation. It deals with the transfer of heat, energy for solids, liquids and gases. It explores the various mechanisms for this heat transfer and laws of thermodynamics, quantifies these mechanisms and applies them to mechanical systems, principally engines and compressors.
Year 2 core modules
Aeroengines and Rocket Science
You look at the fundamental thermodynamics and operational characteristics of a range of engines and their components including gas turbines, jet engines, turbofans, turboshaft engines, ramjets, scramjets and rockets (which are used in aerospace applications) and torque power producing gas turbines (used in industrial and marine applications).
You explore the fundamental thermodynamics of engine operation, the equation for thrust calculations, Mach number, stagnation properties, shock waves, steady one dimensional flow, and analyses of flows through convergent and convergent-divergent nozzles. You learn how to calculate the performance and efficiencies of the engine and its components.
Components include burners and afterburners, compressors, turbine and nozzles. You also look at the calculation and analyses of flows through compressor and turbine blading stages, and fundamentals of rocket propulsion, trajectory analysis, and performance of solid and liquid rocket engines.
You attend a series of keynote lectures as well as problem-solving tutorials and practical investigations.
Applied Mathematical Methods
You develop mathematical knowledge in differential equations and numerical methods and extend your base of techniques to solve a variety of problems which arise in engineering domains. The emphasis is on developing competence in the identification of the most appropriate method to solve a given problem and its subsequent application.
Group Design and Build Project
This is a group project module which is part of the group project theme running through the engineering programmes.
This module will provide you with the opportunity to work in teams in order to solve industrially relevant design problems. In the course of this module, you will develop employability skills such as project management, presentation of work, research and commercial awareness, all of which support problem solving in a technical context.
You learn to use theoretical principles in the practice of creating an engineered design item, through group working activities. A problem based learning approach is adopted and where appropriate, supporting lectures/ seminars will be delivered to include technical knowledge or skills development.
You are assessed through two in-course assignments.
Manufacturing Processes
This module provides you with an insight into current manufacturing processes, promoting a deep understanding of technological factors and an awareness of working principles and capabilities. Traditional methods, such as casting and rolling are examined, together with state-of-the-art practices, such as powder metallurgy. You combine a detailed study of selected manufacturing processes with hands-on experience in laboratory-based practical sessions.
You review important aspects of current thinking, such as quality, reliability, sustainability, lean manufacturing and the extensive use of computers in many areas, to ensure an informed picture of modern manufacturing. You also explore the suitability of manufacturing processes for applications, using a framework that recognises the interrelationships of (manufacturing) process, (artefact) function, shape, and materials.
Mechanics of Materials 1
Mechanics of Materials is a branch of mechanics that studies the relationships between the external loads applied to a deformable body and the intensity of internal forces acting within the body. The subject also involves calculating the deformations of the body, and it provided a study of the body’s stability when the body is subjected to external loadings.
This module examines the essential theories and fundamental principles of mechanics of materials, and develops your knowledge, skills, and ability to apply them in mechanical analysis and design.
Product and Assembly Design Modelling
In this module, you develop your skills and knowledge in applying 3-D solid modelling and surface modelling to product design, using industry standard software. You gain a thorough understanding of computer modeling, and how to apply these skills to design engineering components and products.
You model parts with flat and cylindrical type surfaces, as well as those with more complex curved surfaces. The ability to obtain the mass and other properties of models and create orthographic drawings from 3D models will be covered.
You gain a thorough understanding of both static and dynamic hierarchical assemblies and their value to industry, and learn how to produce ‘Bill of Materials’, undertake clearance and interference checks on mating parts, and Tolerance Analysis.
You acquire the ability to animate dynamic assemblies; you create joints and mechanisms to solve for kinematic motions, and you learn how to structure the models effectively and modify them as appropriate.
Year 3 core modules
Automotive Vehicle Design and Analysis
You gain a sound understanding of the principles related to automotive vehicle design and analysis. And an understanding of the design cycle, from concept to production and the processes required to realise this. You develop an appreciation and understanding of the major components of vehicle design, chassis, drivetrain, engine, braking systems, gearbox and suspension and steering. And understand the implications of regulations and rules governing vehicle design and their impact upon safety and environmental factors.
Dynamics and Vibration
Engineers design, develop, construct and test devices and systems which operate on basic principles of dynamics and vibration. The development of reliable systems depends on the engineer’s understanding of the response of the system to externally applied loads. The system’s response can be predicted using models that may be analytical, numerical or mathematical in nature. The analysis of physical systems to predict their responses to loads is fundamental to the study of engineering mechanics. Dynamics is a branch of mechanics that studies the properties and behaviours of objects in motion.
Integrated Masters Project
This module extends the development of independent learning skills by allowing the student to investigate an area of engineering for an extended period. The student will work independently or in a small team, but will produce individual work.
Training will be given in writing technical reports for knowledgeable readers and the student will produce a report/dissertation of the work covered. In addition, the student will give an oral presentation, poster presentation or both. The topic can be in the form of a research project or a design project. Key skills in research, knowledge application and creation will be developed through keynote lectures and self-managed independent study.
Mechanics of Materials 2
This module will develop the advanced theory and the principles of mechanics of materials and apply them to the analysis of realistic engineering problems. Specific areas of study include: stress concentrations, inelastic deformation and residual stress under axial loading, torsion, and bending as well as transverse shear. Further studies will include introduction to failure theory, design of beams and shafts, deflection of beams and shafts, design of column; thick-walled cylinder and interference fits.
Lectures will introduce each major topic on the module emphasising both the conceptual and theoretical development as well as their applications to realistic engineering problems. Worked examples will be used in the study. Seminars will be utilised primarily for students to practice and to provide feedback.
Laboratory session will be used to investigate the behaviour of components and develop a deeper understanding of the theory and principles.
Sustainable Systems and Industry 4.0
The emergence of Industry 4.0, often referred to as the fourth industrial revolution, has been attributed to advancing automation, decentralisation and system integration and cloud computing. In the cyber-physical environment, machines can communicate, collect information, and make informed decisions through artificial intelligence (AI), big data and industrial internet of things (IIoT). The evolution of Industry 4.0 has great potential to improve the energy, equipment, and human behaviour. At the same time, in the era of the so-called circular economy, industry across all sectors is under huge pressure to make their manufacturing operations ethical and sustainable. Therefore, we must learn to adopt or implement the latest Industry 4.0 technologies.
The term sustainability has a multi-disciplinary use and meaning. As future engineers you will learn sustainability is represented as the synergy between environment, economics, and society. In this module students specialising in Sustainable Systems and Industry 4.0 will focus their studies and deepen their knowledge in a range of sustainability themes such as energy management and power systems, sustainable water and wastewater systems, sustainable transportation technologies, transitions to sustainable food systems and mechanical manufacturing systems.
The subjects will be taught through a combination of lectures and seminars. Lectures will develop key concepts and knowledge. Seminars will allow more focused examinations of important issues and approaches
Optional work placement year
Work placement
You have the option to spend one year in industry learning and developing your skills. We encourage and support you with applying for a placement, job hunting and networking.
You gain experience favoured by graduate recruiters and develop your technical skillset. You also obtain the transferable skills required in any professional environment, including communication, negotiation, teamwork, leadership, organisation, confidence, self-reliance, problem-solving, being able to work under pressure, and commercial awareness.
Many employers view a placement as a year-long interview, therefore placements are increasingly becoming an essential part of an organisation's pre-selection strategy in their graduate recruitment process. Benefits include:
· improved job prospects
· enhanced employment skills and improved career progression opportunities
· a higher starting salary than your full-time counterparts
· a better degree classification
· a richer CV
· a year's salary before completing your degree
· experience of workplace culture
· the opportunity to design and base your final-year project within a working environment.
If you are unable to secure a work placement with an employer, then you simply continue on a course without the work placement.
Final-year core modules
Continuum Mechanics
You develop a unifying, mathematically rigorous approach to mechanics. Through (Cartesian) tensors, you understand a universal framework of mechanical principles, which applies to all materials and integrates classical treatment of fluids and solids with more recent developments in rheology. This theoretical development is put into context through extensive use of examples drawn from “real world” applications.
Enterprising Leadership and Project Management
Enterprise is about spotting opportunities, creating new ideas and having the confidence and capabilities to turn these ideas into working realities. Entrepreneurship is about using enterprise to create new business and new businesses.
This module covers a range of topics related to enterprise, entrepreneurship and the development of an inspirational leader. The skills and knowledge needed to set up and operate an engineering business will be covered. You will review their current approach to leadership, developed in earlier modules and explore your own unique leadership style. You will obtain feedback on your leadership profile from your peers and discover new capabilities. They will clarify your own sense of purpose and learn practises for sustaining yourself, your teams and your organisations.
Lectures and seminars will provide core material and explore case studies. You will work in small facilitated groups during the seminar sessions where you will examine case studies in detail and develop business plans.
Integrated Masters Research Project
This module extends the development of independent learning skills by allowing the student to investigate an area of engineering for an extended period. The student will work independently or in a small team, but will produce individual work.
Training will be given in writing technical reports for knowledgeable readers and the student will produce a report/dissertation of the work covered. In addition, the student will give an oral presentation, poster presentation or both. The topic can be in the form of a research project or a design project. Key skills in research, knowledge application and creation will be developed through keynote lectures and self-managed independent study.
and two optional modules
Advanced Fluid Dynamics
This module covers incompressible and compressible aerodynamics applicable to flight of subsonic and supersonic aircraft, and introduces hypersonic flow applicable to re-entry vehicles.
The content of this module includes a revision of the fundamental fluid flow and thermodynamic governing equations, subsonic and supersonic around wings, flow through nozzles and diffusers, oblique shock waves and expansion waves, fundamentals of boundary layers, convective heat transfer, viscous high temperature flows, and experimental methods for hypersonic flows.
The module content will be delivered through the use of lectures, seminars, laboratory sessions, problem solving tutorials and IT laboratory sessions providing an opportunity to explore complex flows through the use of CFD codes.
Assessment will comprise of a laboratory report compiled from practical laboratory investigations and an end exam.
Finite Element Methods
You gain practical experience of commercially available finite element packages. The application of the method is demonstrated using a number of case studies, and you are encouraged to use the technique as an extension of your standard text books in solving design and manufacturing problems.
Manufacturing Systems
Manufacturing technology is of paramount importance, as no manufacturing industry can exist without it. Modern manufacturing technology entails a diverse range of disciplines and their interaction including Computer Aided Design and Manufacture, Materials, Processes, and Manufacturing Automation.
This module considers typical hardware and software involved with automated machinery and production processes: showing how machines can be integrated into flexible cells and flexible manufacturing systems and, when linked with appropriate production management software, into computer integrated manufacturing systems.
You extend your knowledge and skills within the context of the manufacturing industries, and gain practical experience in the specification, design, and build of an automated manufacturing system You are also introduced to the fundamental concepts for production, utilising lean manufacturing principles and practices and a detailed investigation of a topic of current engineering such as: computer-aided manufacturing, special topics in robotics, and lean/agile manufacturing.
Supply Chain Management
This module investigates a range of applied Quality Management techniques and has been designed to enable students to develop the skills necessary to apply these techniques to their own work environment. This module also examines the appropriate statistical techniques in Quality Control, Auditing, Supply Chain Management and a range of Accreditation Schemes including BRC, EFSIS, ISO, UKAS and Industry Standards. In course assessment (ICA) is via a 5000 words written piece of work, with a weighting of 100%.