The first two years provide a good grounding in the broad fundamentals of mechanical engineering science and engineering design. The science subjects studied include thermodynamics, fluid mechanics, solid mechanics, dynamics and electro-mechanical systems. In design, the emphasis is on project work and in both the first and second years, you will undertake a design, make and test project, which you will manufacture in the department's well-equipped student workshop.
At the end of the second year, you can remain on the BEng course or opt to switch to the four-year MEng degree provided that you have obtained at least 55 percent in the end of year assessment.
Core
Engineering Design and Design Project
In this yearlong module you'll gain a deeper understanding of engineering design principles using practical project work. You'll learn CAD from the ground up, and by the end of the module you'll be well versed in the software.
Further you'll undertake practical workshops, where you'll learn how to use fundamental engineering machinery, which forms the basis of more advanced techniques you'll learn in higher level modules.
Topics covered include:
- Process of design supported by practical design activities
- Engineering drawing CAD solid modelling and drawing generation
- Machine elements Group Design Project with Integrated Individual Element
- Machine shop practical training
Mathematics for Engineers
This module introduces a range of fundamental elementary mathematical techniques that can be applied to mechanical engineering, manufacturing and product design problems.
The aim of the module is to provide engineering students with a base in mathematical knowledge which can then be built on if required in subsequent years, however as a product design student this will be the only maths module you will undertake.
This module includes:
- The calculus of a single variable, extended to develop techniques used in analysing engineering problems
- Advanced differential and integral calculus of one variable
- First-order ordinary-differential equations
- Algebra of complex numbers
- Matrix algebra and its applications to systems of equations and eigenvalue problems
- Functions and their properties
- Vector spaces and their applications
- Vector calculus
Programming, Professional and Laboratory Skills
This year long module comprises a number of elements to provide you with:
- professional engineering, information searching, data analysis, health and safety and oral presentations
- laboratory skills and development of house style laboratory report
- writing and understanding of computer programs including, loops, conditional statements, program flow, functions, basic input output, sound processing, image processing, variables, (1/2D) arrays, advanced plotting and simple computer graphics.
- the application of computer code to control mechanical devices as part of a group project.
- introduction to professional responsibilities of engineers including the fundamental role of sustainability, legal issues, patents, ethics and standards
Statics and Dynamics
The aim of this module is to introduce students to fundamental concepts and principles of solid mechanics and dynamics, and their applications to mechanical engineering systems. A wide range of engineering structures and mechanical components need to be designed to support static loads and as an engineer it is important to understand the way in which forces are transmitted through structures for efficient and safe design. This module includes:
- Static equilibrium: force and moment analysis in design; frictional forces.
- Stress, strain and elasticity.
- Bending stresses in beams.
- Relationship between angular and linear motion.
- Work, energy and power, including kinetic and potential energy.
- Geared systems.
- Static and dynamic balancing.
Materials and Manufacturing
A deep understanding of both materials and manufacturing techniques used to process these materials is essential for all product designers, to produce effective and commercially viable products. This year long module introduces students to the properties of materials, the main failure mechanisms which a designer will be concerned with (e.g overload, fracture, creep, fatigue) and core manufacturing methods used in engineering applications.
It includes the following topics:
- Role of materials and material properties in the design process.
- Selection and use of materials.
- Basic science underlying material properties Approaches to avoid failure of materials.
- Introduction to manufacturing in the UK.
- Casting, machining, moulding, forming, powder processing, heat treatment, surface finishing and assembly.
- Introduction into additive manufacturing an introduction to manufacturing metrology.
Thermodynamics and Fluid Mechanics 1
This is an introductory module covering the fundamental concepts and principles of thermofluids and their applications to engineering problems. Topics covered include:
- introductory concepts; properties of fluids, equations of state and the perfect gas law
- hydrostatics The first and second law of thermodynamics, including heat engines
- fluid dynamics: continuity, Euler and Bernoulli equations
- processes undergone by closed systems
- the steady flow energy equation
- momentum flows including linear momentum, friction factors and pipe flows
- heat transfer
The above is a sample of the typical modules we offer but is not intended to be construed and/or relied upon as a definitive list of the modules that will be available in any given year. Modules (including methods of assessment) may change or be updated, or modules may be cancelled, over the duration of the course due to a number of reasons such as curriculum developments or staffing changes. Please refer to the
module catalogue for information on available modules. This content was last updated on Friday 02 September 2022.
Core
Materials in Design
This module seeks to develop an understanding of materials in design across a wide range of engineering applications. The module is arranged in 4 blocks covering designing with light alloys, polymers, composites, and functional materials. This covers important functional ceramics as well as other functional materials. Each block will explore the design requirements in detail of a particular case study followed by other examples, key material properties relevant to the engineering application, manipulation of the microstructure through processing and example calculations against failure of the product/component. This module will explore:
- Material Attributes
- Engineering Context
- Manufacturing of Material
- Production Processes
- Environmental Impact
Mathematics and Statistics
Design, Manufacture and Project
This module will introduce design methodology through the entire design cycle from establishing users' needs and generating creative concepts to developing fabricable engineered solutions.
You will develop knowledge of machine elements and mechanical systems and develop enhanced skills in communicating effectively in a team environment and operating machine tools for manufacturing and testing of design.
Dynamics and Control
This module aims to introduce concepts of rigid body dynamics, vibrations and feedback control, and develop the student's ability to analyse these aspects in simplified engineering situations.
Electromechanical Devices
This module aims to explain how electricity and electronic principles can be used to achieve practical tasks in mechanical engineering, measure mechanical quantities and provide mechanical power. It also aims to give students an understanding of the importance of electrical and electronic subsystems in mechanical designs.
Topics typically covered in the module are:
- Electrical machines and circuits
- DC circuits, electromagnetism, capacitance, transducers
- AC circuits, rectification, transistors, induction motor, amplifiers, combinational & sequential logic, transformers
- Sensors: application of basic electrical and electronic principles to sensors for position, displacement, velocity, acceleration and strain, rotary sensors
- Actuators: solenoids, stepper motor, DC permanent magnet motor
- Signals and conversion: analog and digital data, ADCs, DACs
Engineering Management 1
This module introduces students to the principles of modern Engineering Management, how projects are selected and financially evaluated, how sustainability is assessed and lifecycle assents are constructed, how health safety and ethics are maintained, and the construction and monitoring of the elements of an engineering or business programme.
The basic concepts and methods relevant to professional management practice are presented, with an emphasis on the commercial engineering context and project management.
Topics include introductions to the following:
- history of management
- private enterprise
- economic theory of the firm
- sustainability and lifecycle assessment
- health, safety and ethics
- financial project evaluation
- project planning and scheduling
- risk management
- project monitoring
Mechanics of Solids
The aim of this module is to introduce more advanced topics in linear elastic solid mechanics, plasticity and failure, introduce relevant analysis methods for this materials behaviour and demonstrate the application of these methods to the design of engineering components.
Thermodynamics and Fluid Mechanics 2
In this module you will apply concepts and principles of thermofluids to fluid mechanics, thermodynamics and heat transfer situations in simplified applied situations.
The above is a sample of the typical modules we offer but is not intended to be construed and/or relied upon as a definitive list of the modules that will be available in any given year. Modules (including methods of assessment) may change or be updated, or modules may be cancelled, over the duration of the course due to a number of reasons such as curriculum developments or staffing changes. Please refer to the
module catalogue for information on available modules. This content was last updated on
The third year of this course is spent in industry. You will receive support in applying for a year-long placement with an appropriate company. During the placement you will significantly enhance your engineering knowledge and skills. You will have regular meetings with your tutor throughout the year and will remain fully registered with the University.
A major individual project makes up a third of your studies. This may involve computational and or experimental investigations often related to research activities within the department. You will also study a mix of compulsory and optional modules, the latter allowing you to tailor the course to your interests.
Core
Engineering Management 2
This module introduces students to concepts and methods relevant to engineering management, with an emphasis on the commercial engineering context.
Topics include introductions to the following:
- impact of digitisation and automation
- operations planning and control, operations management
- financial planning
- financial accounting
- financial analysis
- innovation and new technology
- quality management
- marketing
- new business formation
- business models
- the lean organisation
- management of people
- foundations of contract Law
Computer Modelling Techniques
This module aims to provide students with a basic knowledge and understanding of the main stream computer modelling techniques used in modern engineering practice, including Finite Element, Finite Difference and Finite Volume methods.
Topics covered will include:
- Introduction to numerical methods in engineering
- Finite Element Analysis (FEA) of structures
- Computational Fluid Dynamics (CFD) for thermo-fluids problems
- Coursework on running FEA and CFD software
BEng Individual Project
The project aims to give you experience in the practice of manufacturing engineering at a professional level. It involves the planning, execution and reporting of a programme of work which will normally involve a mixture of experimental, theoretical and computational work together with a review of relevant previous work in the field. The detailed content is a matter for discussion between the student and their supervisor.
Optional
Advanced Dynamics of Machines
This module covers advanced concepts and analytical techniques used to analyse the dynamics of mechanical systems. You will develop understanding, familiarity and knowledge of the analysis techniques required to describe the dynamical and vibration behaviour of mechanical systems moving in 2 and 3 dimensions.
Stress Analysis Techniques
This is an advanced module dealing with experimental, analytical and numerical methods for determining stresses and deformations in complex engineering components. Some of the topics covered include: membrane stresses; Beams on elastic foundations; Bending of flat plates; and experimental stress analysis methods.
Delivery
Activity |
Number of Weeks |
Number of sessions |
Duration of a session |
Lecture |
12 weeks |
1 week |
4 hours |
Assessment method
Assessment Type |
Weight |
Requirements |
Exam |
100.00 |
One 2 hour exam |
Thermofluids
This module introduces the principles of thermodynamics and the thermodynamic concepts relevant to the applications to building environment engineering. Topics covered include: dimensions and units, thermal properties, thermodynamic systems, energy, work and heat transfer processes, perfect gases, steady flow energy equation, 1st law and 2nd law of thermodynamics and basic modes of heat transfer.
Further optional modules within the following subject areas
Aerospace
Automotive
Bioengineering
Design
Human Factors
Materials
Manufacturing
Mechatronics
Sustainability
The above is a sample of the typical modules we offer but is not intended to be construed and/or relied upon as a definitive list of the modules that will be available in any given year. Modules (including methods of assessment) may change or be updated, or modules may be cancelled, over the duration of the course due to a number of reasons such as curriculum developments or staffing changes. Please refer to the
module catalogue for information on available modules. This content was last updated on