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Masters Degrees (Subsea Engineer)

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Subsea engineering plays a vital role in the exploitation of oil and gas resources. The subsea engineering industry help to specify the curriculum so we meet their requirements. Read more
Subsea engineering plays a vital role in the exploitation of oil and gas resources. The subsea engineering industry help to specify the curriculum so we meet their requirements. The course is designed for you as an experienced or recently graduated engineer who wants to develop your subsea knowledge.

Your teaching modules operate in short 'intensive schools' with time after the module to complete the assignments, where applicable. They include:
-Input from industry experts
-Site visits
-Industry-based projects
-Teaching from other disciplines

Teaching consists of lectures, practical sessions, seminars and personal supervision covering a variety of topics in subsea engineering. The degree is taught using a mix of the academic staff from the School of Marine Science and Technology as well as visiting lecturers and experts from industry.

You will undertake a research project leading to a dissertation. This may be a critical review and/or computational or experimental project using the University's world leading testing facilities. The research project is supported by an academic supervisor and may be conducted with an industrial partner which, where appropriate, may be your employer.

Delivery

Ten taught modules worth 120 credits are delivered in blocks through semester one and/or two. A dissertation or research project, worth 60 credits, is undertaken across the three semesters.

Accreditation

Our course is accredited by the Royal Institution of Naval Architects (RINA) and the Institute of Marine Engineering, Science and Technology (IMarEST) on behalf of the Engineering Council. This means that you are automatically recognised as satisfying the educational requirements leading to Chartered Engineer (CEng) status.

The Royal Institution of Naval Architects is an internationally renowned professional institution whose members are involved at all levels in the design, construction, maintenance and operation of marine vessels and structures. Members of RINA are widely represented in industry, universities and colleges, and maritime organisations in over 90 countries.

IMarEST is the first Institute to bring together marine engineers, scientists and technologists into one international multi-disciplinary professional body.

Our accreditations give you an additional benchmark of quality to your degree, making you more attractive to graduate employers. It can also open the door to higher-level jobs, most of which require Chartered Engineer status.

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The goal of structural engineering is to predict the performance of structures under extreme events. This Masters in Structural Engineering provides you with a range of methods to analyse and design structures with quantifiable reliability over their design life. Read more
The goal of structural engineering is to predict the performance of structures under extreme events. This Masters in Structural Engineering provides you with a range of methods to analyse and design structures with quantifiable reliability over their design life.

Why this programme

◾If you intend to pursue a career in this specialist area of civil and structural engineering, in design consultancies and elsewhere, or if you want to transfer from other engineering disciplines, this programme is designed for you.
◾This programme offers a curriculum that is relevant to the needs of industry, designed to provide the advanced education required for the structural engineers of tomorrow.
◾The goal of structural engineering is to predict the performance of structures. This programme empowers future engineers with a range of methods to analyse and design structures with quantifiable reliability over their design life.
◾The University of Glasgow’s School of Engineering has been delivering engineering education and research for more than 150 years and is the oldest School of Engineering in the UK.

Programme structure

Modes of delivery of the MSc in Structural Engineering include lectures, seminars, tutorials, a group design project and individual projects.

Core courses
◾Advanced structural analysis and dynamics
◾Applied engineering mechanics
◾Computational modelling of nonlinear problems
◾Structural concrete
◾Structural design
◾Advanced soil mechanics
◾Structural engineering preliminary research project
◾Structural engineering review project
◾Structural design project

MSc students undertake an additional individual project.

Industry links and employability

If you intend to pursue a career in this specialist area of civil and structural engineering, in design consultancies and elsewhere, or if you want to transfer from other engineering disciplines, this programme is designed for you. It provides the advanced education required for the structural engineers of tomorrow.

Career prospects

This is a new programme which will be delivered the first time in 2016/17. However, it is a continuation of a former Structural Engineering and Mechanics MSc programme. Graduates from the former Structural Engineering and Mechanics programme have gone on to positions such as:

Graduate Structural Engineer at Wood Group PSN
Research Fellow at Fraunhofer Institute High Speed Dynamics
Graduate Structural Engineer at Wood Group
Graduate Structural Engineer at Design ID
Structure Engineer at Fujian United Benefit Broad Sustainable Building Technology
Structural Engineer-Subsea at a structural engineering company
Real Estate Assistant at Icade
Graduate Structure Engineer at P2ML
Graduate Engineer at Technip
Civil Engineering Technical Engineer at Hongrun Construction Corporation
Subsea Project Engineer at Halliburton
Bid and Building Engineer at Jingzhen Construction and Supervision Co.
Graduate Engineer at Reinertsen.

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The Master of Science in Subsea Engineering seeks to prepare highly-trained, highly-qualified, business-aware graduates that can make an immediate impact in their chosen career, and who can address the need for key skills in the subsea industry. Read more
The Master of Science in Subsea Engineering seeks to prepare highly-trained, highly-qualified, business-aware graduates that can make an immediate impact in their chosen career, and who can address the need for key skills in the subsea industry. Subsea Engineering at the University of Aberdeen has a unique relationship with the subsea industry both locally and internationally, and the programme receives contributions from local industrial organisations in terms of relevant and up-to-the minute contributions to teaching, and support in the specification of group and individual projects.

Aberdeen is the heart of the European oil and gas industry, an international hub for companies engaged in Subsea Engineering. A degree from the University of Aberdeen puts you in a unique position to develop business links alongside of learning and developing international skills within the flexible, modular programme.



Full-Time or Part-Time (Distance) Study
===============================
The programme is available as both full-time and part-time (distance learning) study. Distance learning students make use of the University's online virtual learning environment (WebCT) to study via the internet. No attendance at the University is required making it a fully internationally available programme and one which can be studied alongside your career.



About the Programme
=================
The programme seeks to best address the needs of the industry today in terms of subject areas of fundamental importance. The programme objectives are to provide students with:


Increased technical depth and breadth of knowledge and understanding of the development and operation of subsea technologies and systems, from wellhead to topside structure interconnections.

Intellectual and practical skills so that they can apply sound engineering principles and analysis methods to the design and installation of subsea systems, and can use and adapt appropriate analysis tools and techniques, specialist design software and Standards for design improvements and performance optimisation.

The opportunity to further enhance their transferable and personal skills in self-study, communication, report writing, project and time management, and problem solving.

An awareness of the roles and challenges of a practising subsea engineer based on course contents which are tailored to the current and future needs of industry, and therefore provides students with the knowledge and understanding and skills necessary for technical leadership and managerial responsibility.



Syllabus
=======
Students study the following:

Subsea Integrity
Project Management
Subsea Safety and Reliability Management
Subsea Controls
Subsea Construction, Inspection & Maintenance
Pipelines & Soil Mechanics
Riser Systems & Hydrodynamics
Flow Assurance
Individual Project



Assessment
==========
The modules are assessed by a combination of coursework and written examination. The distance learning coursework is submitted to the course tutor through the web-site and marks and comments will be sent back, also via the web, on campus submission is either by email or in person at teaching sessions. Each module has a timetable which details when the coursework is due and when the exam is scheduled to take place. Arrangements can be made for examinations to be taken at a convenient place for you. Distance learning students near to Aberdeen are able to take their examinations at the University.
Examinations are usually held towards the end of January and the end of May. Students sit the examination within their own timezone (e.g. 9am local time).



Teaching
=======
The courses are completely modular in structure and have been carefully developed to articulate to each other to provide a variety of levels of provision, suiting the needs of the participants. A choice of exit levels is provided to suit the needs of the participants thus leading to the award of a postgraduate Certificate, Diploma or MSc qualification. Each level is a necessary requirement for entry to the next one. Full-time students complete 4 modules per half session while part-time students complete up to 2.



Funding
=======
Funding exists for this programme (dependent on eligibility). Please visit http://www.abdn.ac.uk/funding



More Information
=============
More information about this programme can be found on our Postgraduate Prospectus: http://www.abdn.ac.uk/prospectus/pgrad/study/taught.php?code=subsea_engineering

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The Naval Architecture MSc is designed to provide the necessary knowledge and skills in naval architecture theory, analysis and design procedures, as applied to naval and merchant ships, so that students may be easily integrated into industrial ship design teams. Read more
The Naval Architecture MSc is designed to provide the necessary knowledge and skills in naval architecture theory, analysis and design procedures, as applied to naval and merchant ships, so that students may be easily integrated into industrial ship design teams.

Degree information

Students study ship dynamics, ship hydrodynamics, ship structures, the use of computers in advanced engineering analysis, and work in multidisciplinary teams with marine engineers (from the sister Marine Engineering MSc) on a comprehensive and unique ship design exercise. Research skills are honed through project work undertaken in the specialist fields of hydrodynamics, ship dynamics, structures and design.

Students undertake modules to the value of 180 credits.

The programme consists of three core modules (90 credits), a ship design exercise (45 credits) and a research project (45 credits). There are no optional modules for this programme.

Core modules
-Ship Dynamics
-Ship Structures (including subsea structures)
-Ship Hydrodynamics

Dissertation/report
All students complete a ship design group exercise, and undertake an independent research project which explores an aspect of ship design or performance analysis in depth.

Teaching and learning
The programme is delivered through lectures, tutorials, individual and group projects, seminars and coursework assignments, which include advanced computational analysis. Assessment is through written, oral and viva voce examinations and assessed coursework (including the evaluation of technical reports, problem solving exercises, project reports, computational and modelling skills, and oral presentations).

Careers

The Naval Architecture MSc has been accredited, for a period of five years from the 2012 student cohort, by the Institute of Marine Engineering, Science & Technology (IMarEST) as meeting the further learning requirements, in full, for registration as a Chartered Engineer. There is currently a global shortage of well-qualified naval architects and consequently the job prospects are very good.

Top career destinations for this degree:
-Naval Architecture Engineer, French Navy
-Unknown, Canadian Navy
-Graduate Naval Architect, QinetiQ
-Offshore Asset Engineer, Saipem
-Graduate Engineer, Ministry of Defence (MoD)

Employability
UCL Naval Architecture MSc students are highly employable. The programme is designed to embed higher learning through academic study, individual research and a multidisciplinary ship design exercise. It is delivered by leading researchers from across UCL in collaboration with the Ministry of Defence. Students benefit from the close association with both the defence and commercial marine sectors with many lectures delivered by industry and, in some cases, world-leading experts. Networking is further enhanced during the design reviews and final VIP presentations where industry experts provide external challenge, advice and guidance to students while also taking the opportunity to talent-spot.

Why study this degree at UCL?

This MSc has several unique features. Direction and a significant portion of the teaching is carried out by staff seconded from the UK Ministry of Defence with recent experience of leading ship design teams.

The Naval Architecture MSc has been accredited, for a period of five years from the 2012 student cohort, by the Institute of Marine Engineering, Science & Technology (IMarEST) and the Royal Institution of Naval Architects (RINA) as meeting the further learning requirements, in full, for registration as a Chartered Engineer.

The large majority of students of this MSc continue directly to employment in the industry.

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IN THIS INTENSIVE, PART-TIME, 18-MONTH ONLINE PROGRAM YOU WILL GAIN. - Skills and know-how in the latest technologies in E & I oil and gas engineering. Read more
IN THIS INTENSIVE, PART-TIME, 18-MONTH ONLINE PROGRAM YOU WILL GAIN:

- Skills and know-how in the latest technologies in E & I oil and gas engineering
- Tremendous boost to your E & I oil and gas career – no matter whether you are a new graduate or a technician
- Decades of real experience distilled into the course presentations and materials
- Guidance from real E & I oil and gas experts in the field
- Hands-on practical knowledge from the extensive experience of instructors, rather than the theoretical information from books and colleges
- Credibility as the local expert in E & I oil and gas
- Networking contacts in the oil and gas industry
- Improved career prospects and income
- An Advanced Diploma in Electrical & Instrumentation Engineering for Oil and Gas

Next intake is scheduled for September 26, 2017. Applications are now open; places are limited.

INTRODUCTION

There is a growing shortage, and hence opportunity, for Electrical and Instrumentation (E & I) technicians, technologists and engineers in the oil and gas industry. This is due to an increasing need for higher technology methods of obtaining and processing oil and gas as it is a finite declining resource. The technical challenges of extracting oil and gas are becoming ever more demanding, with increasing emphasis on more marginal fields and previously inaccessible zones such as deep oceans, Polar regions, Falkland Islands and Greenland. The aim of this 18-month e-learning program is to provide you with core E & I engineering skills so that these opportunities may be accessed, to enhance your career, and to benefit your firm.

This advanced diploma is presented by lecturers who are highly experienced engineers from industry, having 'worked in the trenches' in the various E & I engineering areas. When doing any course today, a mix of both extensive experience and teaching prowess is essential. All our lecturers have been carefully selected and are seasoned professionals.

This advanced diploma course provides a practical treatment of electrical power systems and instrumentation within the oil, gas, petrochemical and offshore industries. Whilst there is some theory this is used in a practical context giving you the necessary tools to ensure that the Electrical and Instrumentation hardware is delivering the results intended. No matter whether you are a new electrical, instrumentation or control technician/technologist/graduate engineer or indeed, even a practicing facilities engineer, you will find this course beneficial in improving your understanding, skills and knowledge of the whole spectrum of activities ranging from basic E & I engineering to advanced practice including hazardous areas, data communications along with a vast array of E & I equipment utilized in an oil and gas environment.

WHO SHOULD COMPLETE THIS PROGRAM?

This program would be ideal for you if you are seeking to get know-how and expertise in the oil and gas business and are an:

- Instrument and process control technician or technologist
- Instrument fitter
- Chemical or mechanical engineer
- Electrical engineer currently working in a different area to oil and gas
- Experienced electrician
- A recent graduate electrical, instrumentation or mechanical engineer

Even if you are highly experienced you will find this a great way to become familiar with the oil and gas technology as quickly as possible.

COURSE CONTENT

The valuable oil and gas program has five main streams:

- Electrical engineering
- Instrumentation and Control engineering
- General Oil and Gas engineering
- Subsea Instrumentation and Control
- Floating Production, Storage and Offloading (FPSO) Facilities

COURSE FEES

EIT provides distance education to students located almost anywhere in the world – it is one of the very few truly global training institutes. Course fees are paid in a currency that is determined by the student’s location. A full list of fees in a currency appropriate for every country would be complex to navigate and, with today’s exchange rate fluctuations, difficult to maintain. Instead we aim to give you a rapid response regarding fees that is customized to your individual circumstances.

We understand that cost is a major consideration before a student commences study. For a rapid reply to your query regarding courses fees and payment options, please query via the below button and we will respond within 2 business days.

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Our Offshore Engineering MSc provides you with the specialist education necessary to enter the offshore engineering industry. You will specialise in the design, dynamic and strength analysis of fixed and floating offshore oil and gas platforms. Read more
Our Offshore Engineering MSc provides you with the specialist education necessary to enter the offshore engineering industry. You will specialise in the design, dynamic and strength analysis of fixed and floating offshore oil and gas platforms. You will also study subsea systems, including marine systems to produce renewable energy.

Teaching consists of lectures, practical sessions, seminars and personal supervision covering a variety of topics in offshore engineering. You also choose an individual dissertation project. This may be theoretical, experimental or the development of a simulation model of hydrodynamics and/or structural strength of offshore systems. Research strengths include:
-Hydrodynamics of deepwater offshore structures
-Pipeline and subsea systems
-Structural analysis of offshore structures
-Dynamics of mooring and marine riser systems

You will also benefit from participating in projects sponsored directly by industry partners whenever they are available.

Delivery

Seven taught modules worth 100 credits are delivered through semester one and/or two. A dissertation research project, worth 80 credits, is undertaken across the three semesters.

The course is also available with a preliminary year if you do not meet the entry criteria for the one-year MSc course.

Accreditation

Our course is accredited by the Royal Institution of Naval Architects (RINA) and the Institute of Marine Engineering, Science and Technology (IMarEST) on behalf of the Engineering Council. This means that you are automatically recognised as satisfying the educational requirements leading to Chartered Engineer (CEng) status.

The Royal Institution of Naval Architects is an internationally renowned professional institution whose members are involved at all levels in the design, construction, maintenance and operation of marine vessels and structures. Members of RINA are widely represented in industry, universities and colleges, and maritime organisations in over 90 countries.

IMarEST is the first Institute to bring together marine engineers, scientists and technologists into one international multi-disciplinary professional body.

Our accreditations give you an additional benchmark of quality to your degree, making you more attractive to graduate employers. It can also open the door to higher-level jobs, most of which require Chartered Engineer status.

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Running for over 35 years, this fully accredited MSc programme builds advanced capabilities in specialist aspects of bridge engineering. Read more
Running for over 35 years, this fully accredited MSc programme builds advanced capabilities in specialist aspects of bridge engineering.

Successful completion of this programme will aid you in pursuing a career as a bridge engineer with a consultancy, a specialist contractor or a local authority.

PROGRAMME OVERVIEW

Graduate students will find the programme of substantial use in developing their knowledge and skills base for bridge analysis, design and management.

The programme also offers the opportunity for practising bridge engineers to update their knowledge of current design and assessment codes and guidelines, become familiar with developments in new techniques for the design, construction and management of bridges.

The Bridge Engineering programme encompasses a wide range of modules addressing the whole life-analysis of bridge structures from design to end-of-life.

Optional modules from some of our other study streams are also offered, covering structural engineering, geotechnical engineering, water engineering, construction management, and infrastructure engineering and management.

Graduates are highly employable and may progress to relevant specialist PhD or EngD research programmes in the field.

PROGRAMME STRUCTURE

This programme is studied over either one year (full-time) or between two and five years (part-time or distance learning). It consists of eight taught modules and a dissertation project.

This degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Bridge Engineering Group Modules
-Bridge Deck Loading and Analysis
-Prestressed Concrete Bridge Design
-Durability of Bridges and Structures
-Steel and Composite Bridge Design
-Long-Span Bridges

Structural Engineering Group Modules
-Steel Building Design
-Space Structures
-Structural Mechanics and Finite Elements
-Subsea Engineering
-Concrete Building Design
-Structural Safety and Reliability
-Earthquake Engineering
-Design of Masonry Structures

Geotechnical Engineering Group Modules
-Advanced Soil Mechanics
-Energy Geotechnics
-Geotechnical Structures
-Soil-Structure Interaction
-Foundation Engineering

Construction Management Group Modules
-Construction Management and Law
-Construction Organisation
-Project and Risk Management

Infrastructure Engineering and Management Group Modules
-Infrastructure Investment and Financing
-Infrastructure Interdependencies and Resilience
-Infrastructure Asset Management
-Sustainability and Infrastructure

Water and Environmental Engineering Group Modules
-Environmental Health
-Water Treatment
-Wastewater Treatment
-Applied Chemistry and Microbiology
-Pollution Control
-Groundwater Control
-Regulation and Management
-Water Resources Management and Hydraulic Modelling
-Water Policy and Management
-Dissertation
-Dissertation Project

EDUCATIONAL AIMS OF THE PROGRAMME

The programme aims to provide graduates with:
-A comprehensive understanding of engineering mechanics for bridge analysis
-The ability to select and apply the most appropriate analysis methodology for problems in bridge engineering including advanced and new methods
-The ability to design bridge structures in a variety of construction materials
-A working knowledge of the key UK and European standards and codes of practice associated with the design, analysis and construction of bridge structures and the ability to interpret and apply these to both familiar and unfamiliar problems
-The necessary technical further learning towards fulfilling the educational base for the professional qualification of Chartered Engineer

PROGRAMME LEARNING OUTCOMES

The programme provides opportunities for students to develop and demonstrate knowledge and understanding, skills, qualities and other attributes in the following areas:

Knowledge and understanding
-A knowledge and understanding of the key UK and European standards and codes of practice relating to bridge engineering
-The ability to interpret and apply the appropriate UK and European standards and codes of practiceto bridge design for both familiar and unfamiliar situations
-A knowledge and understanding of the construction of different types of bridge structures using different types of materials (e.g. concrete and steel)
-A knowledge and understanding of the common and less common materials used in bridge engineering
-A comprehensive understanding of the principles of engineering mechanics underpinning bridge engineering
-The ability to critically evaluate bridge engineering concepts
-The ability to apply the appropriate analysis methodologies to common bridge engineering problems as well as unfamiliar problems
-The ability to understand the limitations of bridge analysis methods
-A knowledge and understanding to work with information that may be uncertain or incomplete
-A Knowledge and understanding of sustainable development related to bridges
-The awareness of the commercial, social and environmental impacts associated with bridges
-An awareness and ability to make general evaluations of risk associated with the design and construction of bridge structures including health and safety, environmental and commercial risk
-A critical awareness of new developments in the field of bridge engineering

Intellectual / cognitive skills
-The ability to tackle problems familiar or otherwise which have uncertain or incomplete data (A,B)
-The ability to generate innovative bridge designs (B)
-The ability to use theory or experimental research to improve design and/or analysis
-The ability to apply fundamental knowledge to investigate new and emerging technologies
-Synthesis and critical appraisal of the thoughts of others

Professional practical skills
-The awareness of professional and ethical conduct
-A Knowledge and understanding of bridge engineering in a commercial/business context
-Ability to use computer software to assist towards bridge analysis
-Ability to produce a high quality report
-Ability of carry out technical oral presentations

Key / transferable skills
-Communicate engineering design, concepts, analysis and data in a clear and effective manner
-Collect and analyse research data
-Time and resource management planning

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This fully accredited MSc programme helps graduate engineers to acquire advanced capabilities and in-depth knowledge across a range of civil-engineering disciplines, including bridge engineering, construction management, and geotechnical, structural and water engineering. Read more
This fully accredited MSc programme helps graduate engineers to acquire advanced capabilities and in-depth knowledge across a range of civil-engineering disciplines, including bridge engineering, construction management, and geotechnical, structural and water engineering.

This well-established programme is delivered by experienced University staff, together with practising engineers from consultancies and local authorities.

PROGRAMME OVERVIEW

You can access six study streams on this Masters programme:
-Bridge Engineering
-Construction Management
-Geotechnical Engineering
-Structural Engineering
-Water Engineering and Environmental Engineering
-Infrastructure Engineering and Management

As well as supporting the career development of Civil Engineering graduates, this programme provides the necessary further learning for engineers working in the construction industry who hold related first degrees such as engineering geology or construction management.

It is also designed to update the technical skills of practising engineers engaged in the planning, design, construction and operation of civil-engineering works.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time / distance learning for between two to five academic years. It consists of eight taught modules and a dissertation. This degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Structural Engineering Group Modules
-Steel Building Design
-Space Structures
-Structural Mechanics and Finite Elements
-Subsea Engineering
-Concrete Building Design
-Structural Safety and Reliability
-Earthquake Engineering
-Design of Masonry Structures

Bridge Engineering Group Modules
-Bridge Deck Loading and Analysis
-Prestressed Concrete Bridge Design
-Durability of Bridges and Structures
-Bridge Management
-Steel and Composite Bridge Design
-Long-Span Bridges

Geotechnical Engineering Group Modules
-Advanced Soil Mechanics
-Energy Geotechnics
-Geotechnical Structures
-Soil-Structure Interaction
-Deep Foundations and Earth Retaining Structures

Construction Management Group Modules
-Construction Management and Law
-Construction Organisation
-Project and Risk Management

Infrastructure Engineering Group Modules
-Infrastructure Investment and Financing
-Infrastructure Interdependencies and Resilience
-Infrastructure Asset Management
-Sustainability and Infrastructure

Water and Environmental Engineering Group Modules
-Environmental Health
-Water Treatment Optional
-Wastewater Treatment
-Applied Chemistry and Microbiology
-Pollution Control
-Groundwater Control
-Regulation and Management
-Water Resources

Dissertation
-Dissertation Project

EDUCATIONAL AIMS OF THE PROGRAMME

The Civil Engineering programme aims to provide graduate engineers with:
-Advanced capabilities and in-depth knowledge in a range of specialised aspects of civil engineering
-It is also designed to update the technical skills of practising engineers engaged in the planning, design, construction and operation of civil engineering works and to contribute to a personal professional development programme
-A working knowledge of some of the UK and European standards and codes of practice associated with the design, analysis and construction of civil engineering structures and the ability to interpret and apply these to both familiar and unfamiliar problems
-The necessary further learning towards fulfilling the educational base for the professional qualification of Chartered Engineer in both a technical or non-technical capacity dependent upon module selection

PROGRAMME LEARNING OUTCOMES

The programme provides opportunities for students to develop and demonstrate knowledge and understanding, skills, qualities and other attributes in the following areas:

Knowledge and understanding
-The mathematical principles necessary to underpin their education in civil engineering and to enable them to apply mathematical methods, tools and notations proficiently in the analysis and solution of multi-disciplinary open ended engineering problems
-The properties, behaviour and use of relevant materials
-The management techniques which may be used to achieve civil engineering objectives within that context
-Some of the roles of management techniques and codes of practice in design
-The principles and implementation of some advanced design and management techniques specific to civil engineering
-Mathematical and computer models relevant to civil engineering, and an appreciation of their limitations
-The role of the professional engineer in society, including health, safety, environmental, sustainability, ethical issues and risk assessment within civil engineering
-The wider multidisciplinary engineering context and its underlying principles
-Developing technologies related to civil engineering and the ability to develop an ability to synthesize and critically appraise some of them
-The framework of relevant requirements governing engineering activities, including personnel, health, safety, and risk issues (an awareness of)
-The advanced design processes and methodologies and the ability to adapt them in open ended situations.

Intellectual / cognitive skills
-Analyse and solve problems
-Think strategically
-Synthesis of complex sets of information
-Understand the changing nature of knowledge and practice in the management of culturally diverse construction environments
-Select and transfer knowledge and methods from other sectors to construction-based organisation
-Produce sound designs to meet specified requirements such as Eurocodes, deploying commercial software packages as appropriate
-Dynthesis and critical appraisal of the thoughts of others

Professional practical skills
-Awareness of professional and ethical conduct
-Extract data pertinent to an unfamiliar problem, and apply its solution using computer based engineering tools where appropriate
-Evaluate and integrate information and processes in project work
-Present information orally to others
-Show a capability to act decisively in a coordinated way using theory, better practice and harness this to experience
-Use concepts and theories to make engineering judgments in the absence of complete data
-Observe, record and interpret data using appropriate statistical methods and to present results in appropriate forms for the civil engineering industry

Key / transferable skills
-Communicate engineering design, concepts, analysis and data in a clear and effective manner
-Collect and analyse research data
-Time and resource management planning

GLOBAL OPPORTUNITIES

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

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The MSc in Geotechnical Engineering is part of the Division of Civil Engineering's extensive programme of postgraduate studies and research. Read more
The MSc in Geotechnical Engineering is part of the Division of Civil Engineering's extensive programme of postgraduate studies and research. The course builds on the Division's renowned research expertise and industrial experience in current aspects of geotechnical engineering.

Why study Geotechnical Engineering at Dundee?

Key reasons include:
Better preparation for successful careers in industry, commerce or academia
Development of skills, knowledge and understanding in a specialist field
Participation in the research activities of a world-class department

A wide range of research projects are available in any of the following areas: earthquake engineering (foundations during earthquakes, liquefaction, faulting), offshore engineering (foundations, anchors, pipelines and offshore processes), foundation engineering and ground improvement. Some of these projects will be linked to industry

Development of transferable skills in research methods, communication and management of large and small scale projects

Part-time students have the option of relating their research project directly to ongoing work within their employment

Professional Accreditation: ICE/IStructE

This degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree. Visit http://www.jbm.org.uk for further information.

What's great about Geotechnical Engineering at Dundee?

Civil Engineering at Dundee is ranked top in Scotland for research. You will have the opportunity to engage with leading edge research at Dundee, meaning we attract students of the highest calibre and our graduates are highly sought after by employers worldwide. Students studying on our masters programmes benefit from our renowned research expertise and industry experience.

The Geotechnical Engineering research sub-group was established in 1997 and it has grown significantly since that time. In addition to its undergraduate and postgraduate teaching and research activities, the group offers services to industry across a broad range of geotechnical engineering. The group has hosted a number of major conferences and symposia in Dundee.

Who should study this course?

It is designed both for people pursuing a higher degree soon or immediately after obtaining their first degree, and for those with considerable work experience.

"I love how specialised [this course] is, as very few universities offer such speciality in Earthquake and Offshore Engineering. The course taught me how to solve real-life challenging problems, not to mention the strong industry linkage with my future employer - Subsea 7."
Vithiea Pang, MSc student

The start date is September each year, and lasts for 12 months.

How you will be taught

Modules start at the beginning of the academic session in September and are taught by lectures and tutorials.

What you will study

There are three main elements to the course programme:

Core Modules
These provide skills generic to engineering and research. The two modules are:

Research Methods and Diploma Project
Health, Safety & Environmental Engineering
Specialist Modules
The specialist modules provide in-depth and advanced knowledge, and build upon our expertise. These cover the following topics:

Offshore Geotechnical Engineering
Advanced Soil Mechanics and Geo-Environmental Engineering
Soil Dynamics and Earthquake Engineering
Advanced Structural Analysis
Research Project
The research project gives you the opportunity to benefit from, and contribute to our research. At the end of the project students submit a dissertation based on their research. Students select their projects from a list offered by the academic staff or may suggest their own topic. Many of these projects are collaborative with industry, particularly those in offshore engineering (for Oil and Gas, Marine Renewables and Aquaculture)

How you will be assessed

The course is assessed by coursework and examination.

Students taking the Postgraduate Diploma carry out a shorter research project and complete an extended report.

Careers

There is a continuing demand for civil engineers particularly in the energy and water sectors and the skills of the civil engineer are highly portable in the multi-disciplinary engineering sectors. The latest Institution of Civil Engineers Salary Survey for the UK (2010) indicates that the average total income of its senior members is nearly £100k, while that of recent graduates is £27.5k.

We are proud of our achievements in graduate employment. The blend of science, technology and management education and training gained in a unique learning environment that is both challenging and friendly, makes our graduates attractive to employers in civil engineering and a wider range of sectors.

Graduates from Dundee have gone on to achieve high level positions in most sectors of the profession. These include consulting engineers and contractors, the offshore industry and research organisations.

Funded places

Due to an initiative from the Scottish Funding Council (SFC) designed to support key sectors in the Scottish economy, there are 7 fully-funded places available to eligible students starting this course in 2013/14. This covers all tuition fees associated with the MSc programme and can be held by students classified as Scottish or EU for fee purposes only. Please indicate your interest in being considered for a funded place when you apply through UKPASS.

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Our MSc in Advanced Geotechnical Engineering is a European-Accredited Engineering Master Degree programme. It will give you the skills you need to address real-world ground engineering problems and the technological challenges faced every day by the geotechnical engineering profession. Read more
Our MSc in Advanced Geotechnical Engineering is a European-Accredited Engineering Master Degree programme.

It will give you the skills you need to address real-world ground engineering problems and the technological challenges faced every day by the geotechnical engineering profession.

PROGRAMME OVERVIEW

The Advanced Geotechnical Engineering MSc will nurture and develop your understanding of the principles and theories behind ground engineering.

Topics include deep foundations in urban areas, tunnelling, foundations for energy infrastructure, deep water energy resources exploration and field monitoring.

During your studies you will have the opportunity to apply the knowledge and practical understanding of scientific methodology you have acquired on a research project under the guidance and advice of an experienced supervisor.

This will help you develop the skills to acquire, analyse, and critically evaluate data, and then draw valid, defendable conclusions that can withstand professional scrutiny.

Graduates are highly employable, and may progress to relevant specialist PhD or EngD research programmes in the field.

PROGRAMME STRUCTURE

This programme is studied over one academic year (full-time) and between two and five academic years (part-time or distance learning). It consists of eight taught modules and a dissertation.

On successful completion of this MSc programme students will be deemed to have completed the further learning necessary to combine with a suitable BEng (Hons) degree fulfilling the academic base for the professional qualification of Chartered Engineer.

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Geotechnical Engineering Group Modules
-Advanced Soil Mechanics
-Energy Geotechnics
-Geotechnical Structures
-Deep Foundations and Earth Retaining Structures
-Soil-Structure Interaction

Selected Structural Engineering Group Modules
-Subsea Engineering
-Structural Safety and Reliability
-Earthquake Engineering

Selected Construction Management Group Modules
-Construction Management and Law
-Construction Organisation
-Project and Risk Management

Selected Infrastructure Engineering Group Modules
-Infrastructure Systems Interdependencies and Resilience
-Infrastructure Investment and Financing
-Infrastructure Asset Management
-Sustainability and Infrastructure

Selected Water and Environmental Engineering Group Modules
-Groundwater Control
-Water Resources Management and Hydraulic Modelling
-Dissertation project

Students must choose eight modules from those listed above. For the main and subsidiary awards there are restrictions on the choice of modules within each module group. These are outlined in the table above.

EDUCATIONAL AIMS OF THE PROGRAMME

The programme aims to provide graduates with:
-A comprehensive understanding of some of the challenges faced during the analysis, design and construction of foundation and geotechnical structures
-The ability to select and apply most appropriate analysis methodology for problems in ground engineering including advanced and new methods
-The ability to design foundations in a variety of ground conditions
-A working knowledge of the key UK, European and some International standards and codes of practice associated with the analysis and design of foundations and the ability to interpret and apply these to both familiar and unfamiliar problems
-The necessary technical further learning towards fulfilling the educational base for the professional qualification of Chartered Engineer

PROGRAMME LEARNING OUTCOMES

The programme provides opportunities for students to develop and demonstrate knowledge and understanding, skills, qualities and other attributes in the following areas:

Knowledge and understanding
-A knowledge and understanding of the key UK, European and International standards and codes of practice relating to ground engineering
-A knowledge and understanding of the construction of different types of geotechnical structure on different ground conditions
-A comprehensive understanding of the principles of engineering mechanics underpinning ground engineering
-The ability to understand the limitations of ground analysis methods
-The knowledge and understanding to work with information that may be uncertain or incomplete
-A knowledge and understanding of ground engineering in a commercial/business context
-Knowledge and understanding of sustainable development related to ground engineering
-A knowledge and understanding of the common and less common materials used in ground engineering
-An understanding of construction management
-A critical awareness of new developments and research needs in ground engineering

Intellectual / cognitive skills
-The ability to apply fundamental knowledge to investigate new and emerging ground engineering problems
-A critical awareness of new developments in the field of ground engineering
-The ability to critically evaluate ground engineering design principles and concepts
-The awareness of the commercial, social and environmental impacts associated with foundations
-An awareness and ability to make general evaluations of risk associated with the design and construction of foundations including health and safety, environmental and commercial risk

Professional practical skills
-The ability to interpret and apply the appropriate UK, European and some International standards and codes of practice to foundation design for both familiar and unfamiliar situations
-The ability to apply fundamental knowledge to investigate new and emerging technologies
-The ability to apply the appropriate analysis methodologies to common ground engineering problems as well as unfamiliar problems
-The ability to collect and analyse research data
-The ability to tackle problems familiar or otherwise which have uncertain or incomplete data
-The ability to use theory or experimental research to improve design and/or analysis
-The ability to generate innovative foundation design
-The awareness of professional and ethical conduct

Key / transferable skills
-Oral and written communication (presentation skills)
-Synthesis and graphical presentation of data
-3D spatial awareness
-Use of sketching and engineering drafting
-Use of word processor, spreadsheet, drawing/presentation
-Technical report writing
-Independent learning skills
-Ability to develop, monitor and update a plan
-Reviewing, assessing, and critical thinking skills
-Teamwork, leadership and negotiation skills
-Time management

[[GLOBAL OPPORTUNITIES[[
We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

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This well-established and fully accredited MSc programme will develop the knowledge and skills acquired in your undergraduate programme. Read more
This well-established and fully accredited MSc programme will develop the knowledge and skills acquired in your undergraduate programme. It builds the advanced capabilities in analysis and codified design in specialised aspects of structural engineering that are required by industry.

PROGRAMME OVERVIEW

Our Structural Engineering postgraduate programme is delivered by the Faculty’s own staff, together with practising engineers from consultancies and local authorities.

For practising engineers engaged in the planning, design and construction of structural engineering works, this programme provides an opportunity to update their knowledge of current design practice and to become familiar with developments in codes and methods of analysis.

You will be able to choose from a rich and varied selection of specialist structural engineering subjects. The programme is offered in the standard full-time mode, in addition to part-time and distance learning options.

Graduates from the programme are highly employable and may progress to relevant specialist PhD or EngD research programmes in the field.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time or distance learning over two to five academic years. It consists of eight taught modules and a dissertation project.

This degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng (Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree. The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Structural Engineering Group Modules
-Steel Building Design
-Space Structures
-Structural Mechanics and Finite Elements
-Subsea Engineering
-Concrete Building Design
-Structural Safety and Reliability
-Earthquake Engineering
-Design of Masonry Structures

Bridge Engineering Group Modules
-Bridge Deck Loading and Analysis
-Prestressed Concrete Bridge Design
-Durability of Bridges and Structures
-Bridge Management
-Steel and Composite Bridge Design
-Long-Span Bridges

Geotechnical Engineering Group Modules
-Advanced Soil Mechanics
-Energy Geotechnics
-Geotechnical Structures
-Soil-Structure Interaction
-Deep Foundations and Earth Retaining Structures

Construction Management Group Modules
-Construction Management and Law
-Construction Organisation
-Project and Risk Management

Infrastructure Engineering Group Modules
-Infrastructure Investment and Financing
-Infrastructure Interdependencies and Resilience
-Infrastructure Asset Management
-Sustainability and Infrastructure

Water and Environmental Engineering Group Modules
-Environmental Health
-Water Treatment
-Wastewater Treatment
-Applied Chemistry and Microbiology
-Pollution Control
-Groundwater Control
-Regulation and Management
-Water Resources

Dissertation
-Dissertation Project

Apart from the usual full-time mode, there are also part-time options. The majority of Bridge, Geotechnical and Structural Engineering modules can be studied by distance learning through the use of an interactive web-based e-learning platform (SurreyLearn). This programme can be studied via distance learning, which allows a high level of flexibility and enables you to study alongside other commitments you may have.

EDUCATIONAL AIMS OF THE PROGRAMME

The programme aims to provide graduates with:
-A comprehensive understanding of engineering mechanics for structural analysis
-The ability to select and apply the most appropriate analysis methodology for problems in structural engineering including advanced and new methods
-The ability to design structures in a variety of construction materials
-A working knowledge of the key UK and European standards and codes of practice associated with the design, analysis and construction of civil engineering structures and the ability to interpret and apply these to both familiar and unfamiliar problems
-The necessary technical further learning towards fulfilling the educational base for the professional qualification of Chartered Engineer

PROGRAMME LEARNING OUTCOMES

Knowledge and understanding
-A knowledge and understanding of the key UK and European standards and codes of practice relating to structural engineering
-The ability to interpret and apply the appropriate UK and European standards and codes of practice to structural design for both familiar and unfamiliar situations
-A knowledge and understanding of the construction of different types of structures using different types of materials (e.g. concrete and steel)
-A knowledge and understanding of the common and less common materials used in structural engineering
-A comprehensive understanding of the principles of engineering mechanics underpinning structural engineering
-The ability to critically evaluate structural engineering concepts
-The ability to apply the appropriate analysis methodologies to common structural engineering problems as well as unfamiliar problems
-The ability to understand the limitations of structural analysis methods
-A knowledge and understanding to work with information that may be uncertain or incomplete
-A Knowledge and understanding of sustainable development related to structures
-The awareness of the commercial, social and environmental impacts associated with structures
-An awareness and ability to make general evaluations of risk associated with the design and construction of structures including health and safety, environmental and commercial risk
-A critical awareness of new developments in the field of structural engineering

Intellectual / cognitive skills
-The ability to tackle problems familiar or otherwise which have uncertain or incomplete data
-The ability to generate innovative structural designs
-The ability to use theory or experimental research to improve design and/or analysis
-The ability to apply fundamental knowledge to investigate new and emerging technologies
-Produce sound designs to meet specified requirements such as Eurocodes, deploying commercial software packages as appropriate
-Synthesis and critical appraisal of the thoughts of others

Professional practical skills
-The awareness of professional and ethical conduct
-A Knowledge and understanding of structural engineering in a commercial/business context
-Ability to use computer software to assist towards structural analysis
-Ability to produce a high quality report
-Ability of carry out technical oral presentations

Key / transferable skills
-Communicate engineering design, concepts, analysis and data in a clear and effective manner
-Collect and analyse research data
-Time and resource management planning

GLOBAL OPPORTUNITIES

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

Read less
This Marine Technology course is for maritime professionals working full time in Singapore. Our dynamic course responds to the challenges and demands of the global maritime sector. Read more
This Marine Technology course is for maritime professionals working full time in Singapore. Our dynamic course responds to the challenges and demands of the global maritime sector.

This course develops technical and managerial techniques essential to the global maritime sector. You will study key topics including:
-Advanced marine engineering design
-Marine project management
-Marine systems identification, modelling and control
-Regulatory framework for the marine industry
-Surveying ships and offshore installations
-Advanced subsea and pipeline engineering
-Advanced marine design
-Advanced offshore technology
-Advanced hydrodynamics
-Mooring riser and drilling system

Delivery

This course involves a mixture of distance learning and week-long intensive schools delivered in Singapore.

Each taught module consists of 100 notional study hours. 35 hours are at the intensive school. You will need to read and complete course work during your non-intensive study. Each module takes two months and you will undertake a five taught modules per year.

Pre-school materials are provided for you to review what will be taught and so that you get the most out of the intensive school. The pre-school materials are made available four weeks prior to the intensive school.

Each one week intensive school runs from Saturday to Saturday:
-Saturday 14:00 to 18:00
-Sunday 10:00 to 18:00
-Monday to Friday 18:30 to 21:30
-Saturday 14:00 to 18:00

A typical school includes:
-Lectures
-Case studies
-Tutorials
-Presentations
-Discussions
-Visits

You will sit an examination during this intensive teaching week. It is worth 60% of the module mark.

Post-school materials include an assignment worth 40% of the module mark. You will submit this four weeks after the school. This consolidates your learning on a module. You must achieve a mark of 50% or more to pass.

Accreditation

Our course is accredited by the Royal Institution of Naval Architects (RINA) and the Institute of Marine Engineering, Science and Technology (IMarEST) on behalf of the Engineering Council. On graduation you will have satisfied the educational requirements leading to Chartered Engineer (CEng) status.

The RINA is an internationally renowned professional institution. Members work in all levels of design, construction, maintenance and operation of marine vessels and structures. Members of RINA span over 90 countries. They include industry, universities and colleges and maritime organisations.

IMarEST brings together marine engineers, scientists and technologists into one international multi-disciplinary professional body.

Our accreditations give you a benchmark of quality to your degree. They make you more attractive to graduate employers. It can also open the door to higher-level jobs that need CEng status.

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This is the first masters level degree course that brings academic rigour and focus to this multi-disciplinary subject. The MSc in Flow Assurance for Oil and Gas Production is suitable for engineering and applied science graduates who wish to embark on successful careers in the oil and gas industry. Read more
This is the first masters level degree course that brings academic rigour and focus to this multi-disciplinary subject. The MSc in Flow Assurance for Oil and Gas Production is suitable for engineering and applied science graduates who wish to embark on successful careers in the oil and gas industry. Our strategic links with industry ensures that all the materials taught on the course are relevant, timely and meets the needs of organisations competing within the sector. This industry-led education makes our graduates some of the most desirable the world for energy companies to recruit.

In the foreseeable future, hydrocarbon (oil and gas) will still be the major energy source irrespective of the developments in renewable and nuclear energy. The term ‘flow assurance’ was coined by Petrobras in the early 1990s meaning literally “guarantee of flow.” It covers all methods to ensure the safe and efficient delivery of hydrocarbons from the well to the collection facilities. It is a multi-disciplinary activity involving a number of engineering disciplines including mechanical, chemical, process, control, instrumentation and software engineering.

Previously uneconomical fields are now being exploited - oil and gas are produced in hostile environments from deep water to the Arctic. As conventional oil reserves decline, companies are developing unconventional oil fields with complex fluid properties. All of these factors mean that flow assurance plays an increasingly important role in the oil and gas industry.

Course overview

The MSc in Flow Assurance for Oil and Gas Production is made up of nine compulsory taught modules (eight compulsory and one optional from a selection of three), a group project and an individual research project.

In addition to management, communication, team work and research skills, each student will attain at least the following outcomes from this degree course:

- Develop a professional ability to undertake a critical appraisal of technical and/or commercial literature.
- Demonstrate an ability to manage research studies, and plan and execute projects in the area of oil and gas production technology and flow assurance.
- Use of the techniques appropriate for the management of a oil and gas production and transport systems.
- Gain an in-depth understanding of the technical, economic and environmental issues involved in the design and operation of oil and gas production and transport systems.

Group project

The group project runs between February and April and is designed to give students invaluable experience of delivering a project within an industry structured team. The project is sponsored by industrial partners who provide particular problems linked to their plant operations. Projects generally require the group to provide a solution to the operational problem. This group project is shared across the Process Systems Engineering MSc, Flow Assurance MSc and Carbon Capture and Transport MSc, giving the added benefit of gaining new insights, ways of thinking, experience and skills from students with other backgrounds.

During the project you will develop a range of skills including learning how to establish team member roles and responsibilities, project management, and delivering technical presentations. All groups submit a written report and deliver a presentation to the industry partner. Part-time students will take an additional elective module instead of the group project.

It is clear that the modern design engineer cannot be divorced from the commercial world. In order to provide practice in this matter, a poster presentation will be required from all students. This presentation provides the opportunity to develop presentation skills and effectively handle questions about complex issues in a professional manner.

Recent Group Projects include:

- Waste water treatment process design
- A new operation mode design for a gas processing plant.

Individual Project

The individual research project allows students to delve deeper into a specific area of interest. Our industrial partners often put forward practical problems or areas of development as potential research topics. For part-time students, their research project is usually undertaken in collaboration with their place of work. The individual project takes place from April/May to August.

Recent Individual Research Projects include:

- Separation – from Subsea to Topside
- Evaluation of Multiphase Flow Metering
- Multiphase Jet Pumps
- Sand Transport in Undulating Terrains.

Modules

The taught programme for the Flow Assurance masters is generally delivered from October to March and is comprised of eight compulsory modules, and one optional module to select from a choice of four. The modules are delivered over one to two weeks of intensive delivery with the later part of the module being free from structured teaching to allow time for more independent learning and reflection. Students on the part-time programme will complete all of the compulsory modules based on a flexible schedule that will be agreed with the course director.

Assessment

Taught modules: 40%; Group project: 20% (dissertation for part-time students); Individual Research Project: 40%.
The taught modules are assessed by an examination and/or assignment. The Group Project is assessed by a written technical report and oral presentations. The Individual Research Project is assessed by a written thesis and oral presentation.

Funding

Bursaries are available; please contact the Course Director for more information.

Cranfield Postgraduate Loan Scheme (CPLS) - https://www.cranfield.ac.uk/Study/Postgraduate-degrees/Fees-and-funding/Funding-opportunities/cpls/Cranfield-Postgraduate-Loan-Scheme

The Cranfield Postgraduate Loan Scheme (CPLS) is a funding programme providing affordable tuition fee and maintenance loans for full-time UK/EU students studying technology-based MSc courses.

Career opportunities

There is considerable global demand in the oil and gas industry for flow assurance specialists with in-depth technical knowledge and practical skills. The industry led education makes our graduates some of the most desirable for recruitment in this sector. The depth and breadth of the course equips graduates with knowledge and skills to tackle one of the most demanding challenges to secure our energy resource. Graduates of the course can also be recruited in other upstream and downstream positions. Their knowledge can additionally be applied to the petrochemical, process and power industries.

Further Information

For further information on this course, please visit our course webpage - http://www.cranfield.ac.uk/courses/masters/flow-assurance-for-oil-and-gas-production.html

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