Postgraduate Engineering 2024-2025

The course aims to develop a broad understanding about the basic concepts in electrical engineering and power systems with emphasis on renewable power generation techniques.

The course provides an understanding of the flow of hydrocarbon fluids through reservoir rocks and the interplay between the fluid and rock properties and reservoir performance.

This course provides students with an understanding of the fundamentals of well fluids and reservoir testing and the implications for reservoir characterisation and field development. The theory of reservoir pressure testing is introduced, testing methods examined and some of the standard analysis techniques are explored using both hand calculations and industry standard software.

With growing demand on energy, there is increasing need to maximise the production of oil and gas, especially from depleting reservoirs. This course examines the methods and processes of enhanced recovery of oil and gas and provides students with the knowledge and understanding required to develop, acquire and safely integrate enhanced oil recovery technologies into field development plan and field operations.  

The course provides an understanding of theoretical formulation, data sources and integration into simulator, and quantification of uncertainties necessary for transforming real reservoir engineering problems into manageable numerical simulation models.

The MSc in Advanced Chemical Engineering is developed for undergraduate degree holders in chemical or related engineering to equip them with advanced technical skills and knowledge. Separation and Product Purification is a core course of the program. It aims to provide the knowledge and skills related to the existing and emerging separation and product purification technologies in the context of design, optimization, and operation.

The aim of this course is to provide the students with sufficient breadth and depth of prevalent and conventional and emerging separation techniques used in chemical process industries; a significant emphasis will be given to bio-separations used in biotechnology, pharmaceutical, and biomolecules. Other emerging separations in, for example, carbon capture and utilization, environmental protection, etc will be covered.

This course examines the renewable energy industries involving geothermal and hydro sources including resources, physical principles, technologies, environmental considerations and impact, integration into the grid, commercial development, and future challenges facing the industries.

This course provides a detailed understanding of design considerations for components to be used in offshore environments, especially in terms of materials selection, qualification, standards and testing. Reasons for failure and the application of failure analysis in design will be studied. The course will be focussed on offshore steel structures relating to traditional energy applications; however, the fundamental knowledge gained can also be applied to structural integrity assessments in other marine applications including ships, submarines and offshore renewables.This course provides a detailed understanding of design considerations for components to be used in offshore environments, especially in terms of materials selection, qualification, standards and testing. Reasons for failure and the application of failure analysis in design will be studied. The course will be focussed on offshore steel structures relating to traditional energy applications; however, the fundamental knowledge gained can also be applied to structural integrity assessments in other marine applications including ships, submarines and offshore renewables.

This course aims to provide a broad understanding of generation from solar sources, the associated technologies and the main technical challenges.

This course gives students an introduction and overview of energy transition, by focussing on the three key areas of demand, technology and economics. It begins with an introduction to the current energy system and the motivation for an energy transition. There follows a characterisation of the key drivers that underpin our social and economic reliance on energy. Subsequently, behavioural measures and technologies to enable the energy transition are examined and assessed according to diverse technical, economic and environmental criteria.

To develop a broader understanding of carbon capture, its pipeline transportation, utilization and safe underground storage (CCUS) in the geological formations, in terms of the fundamental concepts, their practical applications and their implementation in the ongoing projects.  

Mobile robots can be used in a range of applications, including warehouses, agriculture, and other real-world environments. One of the main challenges for robots operating in the real world is that this is an unstructured environment. Nature has found clever solutions for the design of intelligent and effective systems operating in the unstructured environment hence biology is an obvious source of inspiration for robotics. In this course we take inspiration from nature to engineer intelligent systems for real-world applications as, for example, locomotion.

This course will introduce the key principles in engineering science. Topics cover fluid mechanics, mass and heat transfer, chemical reaction, mechanics in materials and electricity.

Petrophysics, core analysis and formation evaluation are key disciplines in the oil and gas industry and renewable energy such as geothermal energy. It provides the main source of data on porosity, permeability and fluid saturations in the subsurface.  Petrophysics is a crossroad discipline and petrophysicists work closely with geologists and petroleum engineers in exploration and production.  This course provides essential information about petrophysics and core analysis and formation evaluation to allow petroleum engineers to interact effectively with geoscientists.

This course will introduce students to core topics in engineering in medicine, such as the nature and origin of physiological signals, the methods by which those signals are acquired and understood, and how they are used in medical devices. Students will also gain an understanding of the role of biomedical engineers in the design, safe use and management of medical devices.

Gives an overall picture of project management and introduces students to the main subject areas which make up this area of study. Emphasis is placed on practical skills, including writing and presentation. Students are given an overview of project management terms and definitions. Introduction to project budgeting in the context of company finance is addressed and the area of risk management (including probability, risk attitudes and risk analysis methods)
introduced. Introduction to the important area of safety management as well as an introduction to managing project teams. Topics are covered in greater depth at a later stage of the course.

The aim of this course is to get an understanding of applied probability and statistics. Students will be able to handle variables of a random nature, deal with parameters of different distributions and data of scattering nature.

The course provides an introduction to project management and is aimed at students who expect to be working in a project related environment or are considering a potential move into project management. The course covers a number of key aspects of project management from the project managers perspective and so whilst it does cover areas such as planning and estimating it is NOT intended to prepare students for such roles. Students are expected to apply their learning by completing a piece of group project work.

Mobile robots can be used in a range of applications, including warehouses, agriculture, and other real-world environments. One of the main challenges for robots operating in the real world is that this is an unstructured environment. Nature has found clever solutions for the design of intelligent and effective systems operating in the unstructured environment hence biology is an obvious source of inspiration for robotics. In this course we take inspiration from nature to engineer intelligent systems for real-world applications as, for example, locomotion.

The course will provide students an overview of the energy transition, opportunities, and key challenges to reach net-zero carbon societies. It will introduce concepts and ideas useful in more advanced courses involving energy systems based on renewable sources. These will include fundamentals of renewable technologies, economic parameters, basic legal regulations, and societal implications of implementing energy transition projects.

This course will give you an overview of subsea oil and gas production systems and offshore renewables, and an appreciation of the infrastructure and facilities that need to be removed when the time arrives for decommissioning.

You’ll be introduced to various aspects of offshore structures and subsea systems, including wind turbines, subsea oil and gas hardware and pipelines, and their associated infrastructure. You’ll also learn how these systems are maintained and monitored.

This course provides a detailed overview of oil and gas field development from discovery to abandonment with particular focus on the decisions made prior to first production. The roles of uncertainties, economics considerations, safety and environmental impact on the design choices are explored.

Hydrocarbon fires and explosions produce extreme loading on engineering components. Structural steels lose their strength and stiffness well below the temperatures associated with hydrocarbon fires. Safety-critical elements must be designed to withstand both these temperatures and the blast overpressures that result from hydrocarbon explosions. Simple models are used to assess the loading that results from fires and explosions. Structural elements are analysed to illustrate the design procedures that are required to prevent escalation and to design against major accident scenarios.

The course covers design, analysis and operation of subsea production and control systems for various field development options and efficient management of subsea facilities. It introduces the technical and engineering challenges of oil and gas production in subsea fields worldwide, including system reliability, environmental impact and technological advancements. Students will learn about subsea infrastructure and control mechanisms essential for reliable subsea field performance.

This course describes in detail the technologies used to convert biomass into energy. The course covers combustion, gasification, pyrolysis, anaerobic digestion, bioethanol and biodiesel.

The world is full of uncertainties and there is a level of risk in every human activity, including engineering.  Many industries require an engineer to manage significant risks and design for high reliability, such as oil and gas, subsea, nuclear, aviation and large civil projects (e.g. bridges and dams).  To  meet these engineering challenges and make rational decisions in the presence of uncertainty, this course will introduce students to methods and tools used by engineers to analysis risk and reliability.

The course serves as the entrance to the field of safety and reliability engineering with the introduction of the basic concepts and tools of safety and risk management. Legal frames related to engineering safety are also introduced.

Contents include: Fundamentals of safety engineering; natural and man-made hazards; safety measures; accident and failure statistics; fundamentals of risk management; risk assessment techniques; classical reliability theory; modelling of engineering systems as series and parallel systems; redundancy; fault trees and event trees; availability and maintainability; UK safety legislation, including the Health and Safety at Work Act and its historical, offshore and other regulations.

The course aims to give students an in-depth treatment of the critical technical aspects of loss of containment including factors leading to loss of containment and consequence modelling.

This course provides students with an understanding of the engineering science and principles that underpin the drilling of oil and gas well, production technologies, design methodologies, as well as associated safety and environmental considerations.

Course provides a detailed understanding of the techniques used for installation, inspection, and maintenance of subsea systems, including seabed hardware, pipelines and risers, and the implications of such techniques for the design of subsea components and systems.

The module will provide detailed knowledge on various techniques and trends in the installation, inspection and maintenance of subsea equipment, especially pipeline and riser systems and principal components.  It will provide engineers with a sufficiently broad awareness of techniques used throughout offshore operations to give an appreciation and understanding of system limitations and appropriate applications for different subsea environments

The aim of this course is to understand and be able to carry out probabilistic modelling of uncertainty in engineering components and systems. Students will be able to obtain a good knowledge and understanding on random variables in probabilistic analysis and be able to carry out approximation and numerical schemes on components and systems.

To gain an understanding of the need to and the efficiency behind conversion of energy form one form to another and in the need to store energy in distinct forms. To understand the reasoning behind energy losses and how they might be minimised or overcome.

The course aims to develop a broad understanding about the challenges and requirements of integrating renewable generators (RE) to grid, how these requirements can be met using converters, and high voltage direct current (HVDC) as a method of connecting RE to AC grids.

This course provides students with an understanding of the fundamentals of well fluids and reservoir testing and the implications for reservoir characterisation and field development. The theory of reservoir pressure testing is introduced, testing methods examined and some of the standard analysis techniques are explored using both hand calculations and industry standard software.

This course provides students with an understanding of the engineering science and principles that underpin the drilling of oil and gas well, production technologies, design methodologies, as well as associated safety and environmental considerations.

With growing demand on energy, there is increasing need to maximise the production of oil and gas, especially from depleting reservoirs. This course examines the methods and processes of enhanced recovery of oil and gas and provides students with the knowledge and understanding required to develop, acquire and safely integrate enhanced oil recovery technologies into field development plan and field operations.  

The course aims to provide the students with sufficient breadth and depth of knowledge about catalysis and its applications to catalyst design and theory and practice of reactor engineering. The course is developed towards undergraduate degree holders in chemical engineering or related disciplines, such as polymer, petroleum, oil and gas, food and materials engineering, and bioengineering, who aspire to gain advanced technical skills and knowledge in the field of chemical and process engineering.

This course is one of the key courses for the MSc Advanced Structural Engineering. The aim of this course is to provide students with knowledge and skills of analysis and design of lightweight structures for mechanical, civil, aerospace, automotive and wind energy applications. 

The course aims to develop a broad understanding about the renewable energy legislation and of the relevant aspects of economics and safety.

To provide an understanding of the physical principles, technologies and systems associated with renewable energy generation from wind and marine sources. To provide an understanding of the position of these sources of energy in the current and future global energy requirements and the technical challenges in meeting the future energy demand

This course gives students an introduction and overview of Energy Systems Analysis (ESA), including theoretical backgrounds, example models, and hands-on model development and applications. It begins with an introduction to the field of ESA over the past decades, exploring different types of problems and modelling solutions. The course then introduces these different modelling approaches in turn, providing the students with a background in different approaches with their respective pros and cons. Subsequently, we introduce the concept of scenarios as a tool for exploring possible energy system futures.

This course is one of the key courses for MSc Energy Transition. The aim of this course is to provide students with knowledge and skills of critical analysis, multi-criteria assessment and planning of various multi-energy systems by taking into account system integration considerations. The course will provide the opportunity of putting the acquired knowledge and skills into practice by delivering hands on individual and group system integration projects.

Robotics is an essential component of Industry 4.0. The adoption of robots in industries worldwide is on the rise and robotic arms are the most successful robotic platform.

The course introduces students to the analysis and use of robot arms, by exposing them to the theoretical basis of robotics as well as their practical implementation. This course focuses on the kinematics, dynamics and control of robotic arms.

The aim of the course is to give an overview of the different approaches to specify motions of industrial and mobile robots, up to autonomous robots that learn from their experiences. The course introduces students to the fundamentals of machine learning, which are relevant for robotics research and practice. 

Petrophysics, core analysis and formation evaluation are key disciplines in the oil and gas industry and renewable energy such as geothermal energy. It provides the main source of data on porosity, permeability and fluid saturations in the subsurface.  Petrophysics is a crossroad discipline and petrophysicists work closely with geologists and petroleum engineers in exploration and production.  This course provides essential information about petrophysics and core analysis and formation evaluation to allow petroleum engineers to interact effectively with geoscientists.

Risk assessment, the common tools used for (and the legal requirement associated with) risk assessment are covered. Students will have a thorough understanding on the components of good assessment and management of risks, and be familiar with the basic requirement for HAZID, HAZOP, SIL, QRA and the Safety Case.

This course will introduce you to the key principles of ethical research in bioengineering, and cover core topics such as experiment design, basic statistical analysis, and how to review the scientific literature.

Our bodies are shaped by the forces that act on them, and to understand movement, we need to understand the nature of that interaction. In this course, students will learn the basis of human movement in terms of the biomechanics of the musculoskeletal system. They will also appreciate the impacts that disease or injury can have on our ability to move, and gain insight into some of the technologies that can help improve function in people with movement disorders.

Physiological and physicochemical phenomena in biological systems involve complex interactions between tissue, blood and nutrients such as glucose. This course will introduce the principles of biofluid and soft tissue mechanics, and mass transfer phenomena relevant to biological systems. Students will develop the ability to use mathematical modelling to analyse those phenomena, and gain insight into a range of therapies from the perspective of engineering.

Smooth petroleum production requires an understanding of all technical disciplines in facility design and their deliverables as well as of specific new technologies. Competent facilities engineering is needed from concept selection to commissioning and maintenance.

Facilities engineering course focuses on equipment and systems from the well head to the delivery point of the oil and gas industry. This includes not only the processing of the oil and gas but the support systems which might include water treatment, power generation and pollution abatement. 

Fundamental and applied aspects of artificial intelligence (AI), machine learning and data science for petroleum engineers. Use of data from sensors, digital twins and other digital domains during seismic data acquisition, drilling, wireline and logging operations, well testing, reservoir surveillance, production and other oil field operations. Students learn how to optimise sustainable subsurface petroleum production using AI and data science tools to realize net-zero energy future.

The course will provide students an overview of the energy transition, opportunities, and key challenges to reach net-zero carbon societies. It will introduce concepts and ideas useful in more advanced courses involving energy systems based on renewable sources. These will include fundamentals of renewable technologies, economic parameters, basic legal regulations, and societal implications of implementing energy transition projects.

This course will give you an overview of subsea oil and gas production systems and offshore renewables, and an appreciation of the infrastructure and facilities that need to be removed when the time arrives for decommissioning.

You’ll be introduced to various aspects of offshore structures and subsea systems, including wind turbines, subsea oil and gas hardware and pipelines, and their associated infrastructure. You’ll also learn how these systems are maintained and monitored.

This course provides a detailed overview of oil and gas field development from discovery to abandonment with particular focus on the decisions made prior to first production. The roles of uncertainties, economics considerations, safety and environmental impact on the design choices are explored.

Offshore production of oil and gas requires transportation of the oil and gas from where it is produced to shipping vessels, storage tanks or refinery.  The transportation is done using pipelines which are installed on the seabed. This course examines the engineering and scientific concepts that underpin the selection of the material and size of such pipelines as well as safe installation and operation. The environmental impact and the role played by the seabed profile are also discussed. Contribution from industry-based practicing engineers is used to inform students of current practices and technologies in subsea pipelines.

There are many challenges during transport of oil and gas through pipelines. These challenges require a real grasp of the fundamentals in fluid mechanics, heat transfer, phase changes, deposition and/or obstruction, erosion and new technologies to ensure a reliable and cost effective provision of oil and gas. Deep water production, heavy oils, high water production, severe slugging, hydrates, sour gases, asphaltenes and waxes make this task even harder. This course will provide a detailed explanation of the topics, a well-balanced set of tutorials with real examples, invited lectures from experienced engineers and flow assurance specific software training.

The course provides students with detailed knowledge of risers systems design considerations. Typical riser systems including flexible, steel catenary, hybrid and top tensioned riser systems are covered. The ocean environmental hydrodynamics and interactions between vessel, mooring and riser systems are also considered.

The background to the finite element method and its use in various industrial applications is explained in this course. As well as the modelling of linear static and dynamic problems, the modelling of material and geometric non-linearity is an important aspect of the course. Coursework assignments will be based on the student edition of ABAQUS which is supplied with the Course Textbook which students are required to purchase.

The world is full of uncertainties and there is a level of risk in every human activity, including engineering.  Many industries require an engineer to manage significant risks and design for high reliability, such as oil and gas, subsea, nuclear, aviation and large civil projects (e.g. bridges and dams).  To  meet these engineering challenges and make rational decisions in the presence of uncertainty, this course will introduce students to methods and tools used by engineers to analysis risk and reliability.

The course aims to give students knowledge and understanding of how larger process systems behave and are operated and controlled.  Focus is being placed on the stability of feedback control loops and on advanced control strategies aiming at enhancing safety and operability.  Specific cases across the safety hierarchy (basic and advanced process control, alarm systems, emergency shutdown and interlocks, etc) are addressed.

Candidates will develop PIDs for major systems applying LOPA and including instrumentation. Inherently safe equipment layout principles for both onshore and offshore applications are addressed.  Layouts will be developed for example applications.

The safety critical systems are reviewed and discussed.

Corrosion mechanisms are addressed together with materials for construction properties.  Basic corrosion models are presented for a wide range of fluids.  The operational modes which present most demand on materials are reviewed.  Corrosion in erosive environments is addressed.  Effects of temperature deviations in fire & blowdown are illustrated and analysed.  Case studies are used to illustrate common issues.

Human Factors Engineering (HFE) relates to how people interact with engineering systems. Failures in these areas are involved in all major incidents. Candidates explore them as part of this course. First, a review of major accidents will be undertaken to identify how equipment design, individual behaviours, and organisational behaviours contributed. Equipment/system design and the effect it has on individuals' behaviours is explored. Human Error is addressed. Finally, organisational behaviours will be examined. Leading and Lagging indicators are explored and their strengths/weaknesses considered. Candidates have the opportunity to complete practical assessments led by industry practitioners with specialist expertise in HFE.

Decommissioning of oil and gas infrastructure is becoming a major issue for the North Sea and other mature basins.  This course provides students with an overview of the stages of shutting down the production process and cleaning of the system and then the possible methods of removal of the structure.

Decommissioning of oil and gas infrastructure is becoming a major issue for the North Sea and other mature basins.  This course provides students with an insight into the process used to find the best decommissioning option for a particular installation, taking account of the complex interactions between, cost, technical feasibility, environmental and societal considerations and safety. 

The MSc Individual Project is an independent piece of research based on a topic related to a student’s degree programme. Students are encouraged to focus on a problem confronting industry or a related area. The individual project provides students with an opportunity to demonstrate how the in-depth skills and knowledge they have gained during the taught courses can be used to provide solutions to practical problems. The individual project should contain a degree of original research.

This course enables students to write a dissertation based on a subsea related topic of the student’s own choice. Students are encouraged to focus their dissertation on a problem confronting the Subsea industry.

The MSc Individual Project is an independent piece of research based on a topic related to a student’s degree programme. Students are encouraged to focus on a problem confronting industry or a related area. The individual project provides students with an opportunity to demonstrate how the in-depth skills and knowledge they have gained during the taught courses can be used to provide solutions to practical problems. The individual project should contain a degree of original research.