Civil Engineering

Core modules:

Research and Professional Skills

This module fosters best practice in engineering-related research/professional skills and delivers a range of training activities to meet the needs of professional engineers dealing with research and technological development.

15 credits

Advanced Engineering Research Study

This module represents a major element of the Masters programme, with the aim of enabling you to learn skills in scientific investigation and in running and presenting a project. You are required to submit a comprehensive (bound) report describing the individual work that you have done during the summer semester.

60 credits

Optional modules:

Computational Structural Analysis

This module will cover the theoretical and practical aspects of using numerical analysis methods, with emphasis on the Finite Element Method (FEM). The module starts with the fundamentals of the FEM to then cover practical applications to structural problems and interpretation of results. Additionally, it provides an overview of recent developments in computational structural analysis.

15 credits

Structural Dynamics and Earthquake Engineering

This module is designed to provide you with a systematic knowledge and understanding of structural dynamics and its applications in Civil Engineering. On successful completion of this module, you will be able to perform calculation and analyse vibration response of single-degree-of-freedom and multi-degree-of-freedom systems and apply simple structural dynamics theory to solve practical problems in earthquake engineering.

15 credits

Engineering within Planetary Capacity

It is projected that by 2050 the human population will be 10 billion, with over 75% concentrated in urban and megacity areas. It is essential that engineering solutions are developed to create and maintain an urban built environment that can meet rapidly changing societal needs, whilst being within the carrying capacity of the planet. This module will equip you with the skills to develop and analyse built environment engineering solutions to ensure they operate within planetary boundaries.

15 credits

Civil Engineering Project Management

This module will introduce you to core management topics and skills relevant to the complex environment of the modern construction industry. Key topics addressed include: construction project management, making a business case, understanding value, risk and quality, managing resources and contracts, legal responsibilities and procurement.

15 credits

Engineering Hydrology and Hydrogeology

This module is intended to provide an introduction to Hydrology and Hydrogeology for MSc Water Engineering and MSc Civil Engineering students, to equip you with basic quantitative skills for conducting mass balance calculations as well as hydrological and hydrogeological investigations. The module content comprises the prediction of rainfalls, quantitative and qualitative analysis of water movement over the surface and through the subsurface, the estimation of flood flows, the study of hydrologic and hydrogeological processes along with the range of space and time scales at which they occur, an overview of hydrological and hydrogeological measurement techniques, and an overview of current issues in the field, such as climate change.

15 credits

Innovations in Construction Materials and Technologies

This research-led module will familiarise students with some of the innovative materials and technologies used in the construction industry for the design and execution of new structures and the rehabilitation of existing infrastructure. The module will deal with: the use of innovative solutions for reinforcing and strengthening concrete structures (e.g. Fibre Reinforced Polymers - FRP, Textile Reinforced Mortars - TRM); the development of Ultra High Performance Concrete (UHPC) and its structural applications; the development of low-carbon sustainable concretes, including geopolymer concrete, and their applications; recent material and product developments (e.g. self-healing concrete), state-of-the-art additive construction techniques (e.g. concrete 3D printing). Existing design guidelines and state-of-the-art research in the field will be reviewed and discussed, and complemented by practical tutorials, seminars and laboratory sessions.

15 credits

Advanced Geotechnics

This module is designed to (i) deepen your understanding of the fundamentals of soil behaviour, (ii) develop your understanding of the use of limit analysis in geotechnical engineering and (iii) describe the concepts behind geotechnical limit state design and how safety idealisations are used to deal with the complexities of soil behaviour in a sustainable manner. Through lectures, tutorial sheets, and software exercises, you will develop your knowledge of geotechnical design with reference to Eurocode 7. You will also develop your ability to use a range of state-of-the-art engineering design concepts and tools, all aimed at promoting sustainability and efficiency in engineering practice.

15 credits

Engineering Hydraulics

This module aims to provide a solid base for the analysis of water flows in closed and open ducts. The module provides basic physical insights of the dynamics of laminar and turbulent flows in pipes and open channels. It will also give you a detailed overview of the governing equations and assumptions involved in their application at different scales of analysis. You will gain understanding and competence in the analysis of flows in different contexts and the practical application of these to solve common water engineering problems.

15 credits

Managing Design and Construction

This module will apply core skills taught in previous modules to real life scenarios related to the management of construction. The scenarios will include aspects of: construction project management, making a business case, understanding value, risk and quality, managing resources and contracts, legal responsibilities and procurement.

15 credits

Geotechnical Infrastructure

The module will focus on the analysis and sustainable design of large scale geotechnical infrastructure and systems, such as embankment dams, levees and tunnels. Aspects of uncertainty and risk, particularly in the context of a changing climate, will be developed related to ultimate and serviceability limit states, using a range of historical case histories within the published literature. A forensic investigative analysis will be conducted on a case study of geotechnical failure, benefiting from data from the literature and numerical modelling. This will be complemented by a consideration of soil acting as both a continuum and as a particulate system, and by an examination of the role of physical modelling, analytical models, constitutive models, and the geological model.

15 credits

Advanced Concrete Design for Net-Zero

This module is designed for individuals with a background in reinforced concrete structure design, offering an in-depth exploration of advanced topics in the field. Focusing on emerging concepts, construction techniques, and innovative materials, the course places particular emphasis on materials conducive to achieving Net Zero Carbon and examines their implications in the design process. The module not only revisits fundamental principles of reinforced concrete design but also delves into key aspects such as short and long-term deflections, creep, shrinkage, ductility, section analysis, prestressing, shear, and cracking. This module equips participants with the knowledge and skills necessary to navigate the complexities of modern reinforced concrete design.

15 credits

Sustainable Steel and Hybrid Structures

This module will provide students with up-to-date knowledge of steel and hybrid construction and prepare them with skills for designing steel, steel-concrete hybrid and steel-timber hybrid structures.  The module will help the students to develop a fundamental understanding of the underlying principles of the behaviour of these structures, as well as sustainability and modern constructions methods, such as design for disassembly and adaptability.

15 credits

Regenerative Design Project

This module involves working in groups to address a complex, real-world engineering problem. The module will involve receiving, interrogating, and developing a project brief, then drawing on myriad sources to develop options. Students will conduct stakeholder engagement and systems thinking to develop options which meet ecological, ethical, social and technical needs. In doing so will develop holistic concept / scheme stage designs, using engineering calculations to rapidly validate design options, and to inform decision making. Students will then communicate their proposals and reflect on their learning.

15 credits

Design and Management of Sewer Systems

This module will provide students with a high level of knowledge and understanding as to how sewer and stormwater drainage systems operate in the UK. Teaching will focus on acquiring knowledge about current and emerging regulatory, management and design practices. Students will be required to understand the environmental and sustainbility issues associated with this type of infrastructure system. Students will apply industry standard design approaches in a case study, considering hydraulic and pollution concepts to evaluate and modify the performance of the case study network to meet current regulatory requirements, anticipated future pressures whilst considering the long term sustainability of the system. Students will be expected to demonstrate their level of knowledge and understanding via application in the case study sewer network.

15 credits