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Masters Degrees (Process Simulation)

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The MSc Process Systems Engineering programme will widen your understanding of the fundamental concepts of process systems engineering. Read more
The MSc Process Systems Engineering programme will widen your understanding of the fundamental concepts of process systems engineering.

It will provide you with a thorough grounding in current technologies and trends that will prepare you will for a rewarding career and/or further research.

PROGRAMME OVERVIEW

This Masters programme trains graduates of engineering, science or related disciplines in general and specialist process systems engineering subjects.

Such areas are not generally covered in engineering and science curricula, and BSc graduates tend to be ill prepared for the systems challenges they will face in industry or academia on graduation.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year. It consists of eight taught modules and a dissertation. 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.
-Optimisation and Decision-Making
-Process Modelling and Simulation
-Advanced Process Control
-Renewable Energy Technologies
-Refinery and Petrochemical Process
-Technology, Business & Research Seminars
-Process and Energy Integration
-Process Systems Design
-Supply Chain Management
-Knowledge-based Systems and Artificial Intelligence
-Biomass Processing Technology
-Introduction to Petroleum Production
-Process Safety and Operation Integrity
-Dissertation

FACILITIES, EQUIPMENT AND ACADEMIC SUPPORT

Modules related to the different groups are taught by a total of six full-time members of staff and a number of visiting lecturers.

As part of their learning experience, students have at their disposal a wide range of relevant software needed to support the programme material dissertation projects. In recent years, this work included the design of various knowledge-based and business systems on the internet, the application of optimisation algorithms, and semantic web applications.

Numerous laboratory facilities across the Faculty and the University are also available for those opting for technology-based projects, such as the process engineering facility, a control and robotics facility and signal processing labs.

The work related to the MSc dissertation can often be carried out in parallel with, and in support of, ongoing research. In the past, several graduates have carried on their MSc research to a PhD programme.

CAREER PROSPECTS

Engineers and scientists are increasingly expected to have skills in information systems engineering and decision-support systems alongside their main technical and/or scientific expertise.

Graduates of this programme will be well prepared to help technology-intensive organisations make important decisions in view of vast amounts of information by adopting, combining, implementing and executing the right technologies.

EDUCATIONAL AIMS OF THE PROGRAMME

The programme aims to provide a highly vocational education which is intellectually rigorous and up-to-date. It also aims to provide the students with the necessary skills required for a successful career in the process industries.

This is achieved through a balanced curriculum with a core of process systems engineering modules supplemented by a flexible element by way of elective modules that permit students to pursue an element of specialisation relevant to their backgrounds, interests and/or career aspirations.

An integrated approach is taken so as to provide a coherent view that explores the interrelationships between the various components of the programme. The programme draws on the stimulus of the Faculty’s research activities.

The programme provides the students with the basis for developing their own approach to learning and personal development.

PROGRAMME LEARNING OUTCOMES

Knowledge and understanding
-State-of- the-art knowledge in process systems engineering methods, in the areas of: modelling and simulation of process systems, mathematical optimization and decision making, process systems design, supply chain management, process and energy integration, and advanced process control technologies
-Advanced level of understanding in technical topics of preference, in one or more of the following aspects: renewable energy technologies, refinery and petrochemical processes, biomass processing technologies, and knowledge-based systems

Intellectual / cognitive skills
-Select, define and focus upon an issue at an appropriate level
-Collect and digest knowledge and information selectively and independently to support a particular scientific or engineering enquiry
-Develop and apply relevant and sound methodologies for analysing the issue, developing solutions, recommendations and logical conclusions, and for evaluating the results of own or other’s work

Professional practical skills
-Assess the available systems in the process industries
-Design and/or select appropriate system components, and optimise and evaluate system design
-Apply generic systems engineering methods such as modelling, simulation, and optimization to facilitate the assessment and development of advanced process technologies and systems

Key / transferable skills
-Preparation and delivery of communication and presentation
-Report and essay writing
-Use of general and professional computing tools
-Collaborative working with team members
-Organising and planning of work
-Research into new areas, particularly in the aspect of literature review and skills acquisition

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 programme delivers a thorough grounding in current technologies and trends, offering comprehensive training in the fundamentals of the subject. Read more
This programme delivers a thorough grounding in current technologies and trends, offering comprehensive training in the fundamentals of the subject.

It combines high-quality education with rigorous intellectual challenges, enabling you to understand the principles of knowledge management, decision-making and design in process systems and business-information technologies.

PROGRAMME OVERVIEW

The MSc Information and Process Systems Engineering programme is aimed at graduates of traditional engineering, science and related disciplines.

Graduates from non-IT or related disciplines tend to be ill-prepared for the information and knowledge-related challenges and demands of today’s business environments.

We offer a wide selection of modules spanning process engineering, information systems, business and management. All taught modules are delivered by qualified experts in the topics and academic staff, assisted by specialist external lecturers.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year. Part-time students must study at least two taught technical modules per academic year. The programme consists of eight taught modules and a dissertation. 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.
-Information Security Management
-Optimisation and Decision-Making
-Process Modelling and Simulation
-Technology, Business and Research Seminars
-Database Systems
-Knowledge-Based Systems and Artificial Intelligence
-Process and Energy Integration
-Process Systems Design
-Supply Chain Management
-Biomass Processing Technology
-Process Safety and Operation Integrity
-Process and Energy Integration
-Transition to a Low Carbon Economy
-Dissertation

FACILITIES, EQUIPMENT AND ACADEMIC SUPPORT

Modules related to the different groups are taught by a total of six full-time members of staff and a number of visiting lecturers.

An extensive library is available for individual study. It stocks more than 85,000 printed books and e-books, and more than 1,400 (1,100 online) journal titles, all in the broad area of engineering. The library support can be extended further through inter-library loans.

As part of their learning experience, students have at their disposal a wide range of relevant software needed to support the programme material dissertation projects.

In recent years, this work included the design of various knowledge-based and business systems on the internet, the application of optimisation algorithms, and semantic web applications, as well as modelling of process systems.

Numerous laboratory facilities across the Faculty and the University are also available for those opting for technology-based projects, such as the process engineering facility, a control and robotics facility and signal processing labs.

The work related to the MSc dissertation can often be carried out in parallel with, and in support of, on-going research. In the past, several graduates have carried on their MSc research to a PhD programme.

RESEARCH

Process integration and systems analysis for sustainability of resources and energy efficiency are carried out within our well-established Centre for Process and Information Systems Engineering (PRISE).

CAREER PROSPECTS

Engineers and scientists are increasingly expected to have skills in information systems engineering and decision support systems alongside their main technical and/or scientific expertise.

Graduates of these programmes will be well prepared to help technology-intensive organisations make important decisions in respect of vast amounts of information, by adopting, combining, implementing and executing the right technologies.

EDUCATIONAL AIMS OF THE PROGRAMME

The primary aims are achieved through a balanced, multi-disciplinary curriculum with a core of information systems engineering modules and decision-making and process systems engineering modules as well as a flexible element by way of elective modules that permit students to pursue an element of specialisation relevant to their backgrounds, interests and/or career aspirations.

An integrated approach is taken so as to provide a coherent view that explores the interrelationships between the various components of the programme.

The programme draws on the stimulus of recent research activities in the Faculty of Engineering and Physical Sciences. The programme provides the students with the basis for developing their own approach to learning and personal development.

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 sources, technologies, systems, performance, and applications in information and process engineering
-Approaches to the assessment of information and process technologies
-Decision making in complex systems
-Optimisation and operations research
-Technical systems modelling
-Databases and data protection
-Representation of design processes
-Systematic approaches to observing organisational data security processes
-Understanding research issues
-Literature studies and research planning
-Experimental planning
-Communication of research outcomes
-Design of decision-support systems
-Development of databases, ontologies and agent-based architectures
-Information technology and security
-Process modelling and simulation

Intellectual / cognitive skills
-Select, define and focus upon an issue at an appropriate level
-Collect and digest knowledge and information selectively and independently to support a particular scientific or engineering enquiry
-Develop and apply relevant and sound methodologies for analysing the issue, developing solutions, recommendations and logical conclusions, and for evaluating the results of own or other’s work

Professional practical skills
-Assess the available information and process and their interaction
-Design and select appropriate collection and storage, and optimise and evaluate system design
-Apply generic systems engineering methods such as conceptual design and optimization to facilitate the assessment and development of information, information security and process technologies and systems

Key / transferable skills
-Preparation and delivery of communication and presentation
-Report and essay writing
-Use of general and professional computing tools
-Collaborative working with team members
-Organizing and planning of work
-Research into new areas, particularly in the aspect of literature review and skills acquisition

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
With an increasing awareness of the environmental impact of modern manufacturing, graduates with the combined skills taught on this programme are highly sought after by both process and environmental industries. Read more
With an increasing awareness of the environmental impact of modern manufacturing, graduates with the combined skills taught on this programme are highly sought after by both process and environmental industries.

If you want to develop core skills in process systems engineering, yet focusing your attention on environmental systems approaches, this Masters is for you.

PROGRAMME OVERVIEW

This programme explores technology across a wide scope of engineering disciplines and will train you in general and specialist process systems engineering – crucial aspects for finance, industrial management and computer-integrated manufacturing.

There is a wide selection of modules on offer within the programme. All taught modules are delivered by qualified experts in the topics and academic members of University staff, assisted by specialist external lecturers.

Our programme combines high-quality education with substantial intellectual challenges, making you aware of current technologies and trends while providing a rigorous training in the fundamentals of the subject.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year. It consists of eight taught modules and a dissertation. 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.
-Life Cycle Thinking
-Optimisation and Decision-Making
-Renewable Energy Technologies
-Process Modelling and Simulation
-Solar Energy Technology
-Advanced Process Control
-Technology, Business and Research Seminars
-Environmental Law
-Sustainable Development Applications
-Process and Energy Integration
-Process Systems Design
-Dissertation

EDUCATIONAL AIMS OF THE PROGRAMME

The programme combines advanced material in two popular and complementary topics: systems engineering and environmental engineering. The key learning outcome is a balanced combination of systems and environmental skills and prepares students in a competitive market where both topics appear attractive.

The programme will provide training in general and specialist process and environmental systems engineering subjects, and prepare the students for the systems challenges they will face in industry or academia upon graduation.

The programme disseminates technology with a wide scope among engineering disciplines, with a wide selection of modules on offer. All taught modules are delivered by qualified experts in the topics and academic members of the university staff, assisted by specialist external lecturers.

The programme provides high-quality education with substantial intellectual challenges, commensurate with the financial rewards and job satisfaction when venturing into the real world. A key component is to make the student aware of current technologies and trends, whilst providing a rigorous training in the fundamentals of the subject.

PROGRAMME LEARNING OUTCOMES

Knowledge and understanding
-State-of- the-art knowledge in process and environmental technologies, in the areas of: life cycle assessment and sustainable development, modelling and simulation of process systems, mathematical optimization and decision making, process systems design, and process and energy integration
-Advanced level of understanding in technical topics of preference, in one or more of the following aspects: general renewable energy technologies, and solar energy in particular; advanced process control

Intellectual / cognitive skills
-Select, define and focus upon an issue at an appropriate level
-Collect and digest knowledge and information selectively and independently to support a particular scientific or engineering enquiry
-Develop and apply relevant and sound methodologies for analysing the issue, developing solutions, recommendations and logical conclusions, and for evaluating the results of own or other’s work

Professional practical skills
-Assess the available systems in the process industries with focus on environmental challenges
-Design and/or select appropriate system components, and optimise and evaluate system design
-Apply generic systems engineering methods such as modelling, simulation, and optimization to facilitate the assessment and development of advanced process and environmental technologies and systems

Key / transferable skills
-Preparation and delivery of communication and presentation
-Report and essay writing
-Use of general and professional computing tools
-Collaborative working with team members
-Organising and planning of work
-Research into new areas, particularly in the aspect of literature review and skills acquisition

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
Created in response to the worldwide shortage of qualified engineers in the petroleum-refining systems-engineering industry, our programme combines technologies, operations and economics with modelling, simulation, optimisation, and process design and integration. Read more
Created in response to the worldwide shortage of qualified engineers in the petroleum-refining systems-engineering industry, our programme combines technologies, operations and economics with modelling, simulation, optimisation, and process design and integration.

PROGRAMME OVERVIEW

This programme will equip you with the essential knowledge for engineering careers in the oil, gas and petrochemical sectors.

Upon completion of the course you will have gained a comprehensive understanding of oil refining and associated downstream processing technologies, operations and economics; process safety and operations integrity; and methods for the optimal design of process systems.

You will learn about the general economics of the energy sector, oil exploration and production, as well as renewable energy systems.

Furthermore, your study of the various aspects of petroleum refining will be augmented by unique work assignments at a virtual oil-refining and chemical company.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year. It consists of eight taught modules and a dissertation. 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.
-Optimisation and Decision-Making
-Process Modelling and Simulation
-Refinery and Petrochemical Process
-Renewable Energy Technologies
-Solar Energy Technology
-Advanced Process Control
-Technology, Business & Research Seminars
-Energy Economics and Technology
-Process and Energy Integration
-Process Systems Design
-Process Safety and Operation Integrity
-Knowledge-based Systems and Artificial Intelligence
-Supply Chain Management
-Biomass Processing Technology
-Introduction to Petroleum Production
-Wind Energy Technology
-Economics of International Oil & Gas
-Dissertation

EDUCATIONAL AIMS OF THE PROGRAMME

The programme aims to provide a highly vocational education that equips the students with the essential knowledge and skills required to work as competent engineers in the petrochemical sector.

This is to be achieved through combining proper material in two popular and complementary topics: process systems engineering and petroleum refining. The key objective is to develop a sound understanding of oil refining and downstream processing technologies, process safety and operation integrity, as well as systems methods for the optimal design of process systems.

A balanced curriculum is provided with essential modules from these two areas supplemented by a flexible element by way of elective modules that permit students to pursue subjects of preference relevant to their backgrounds, interests and/or career aspirations.

An integrated approach is taken so as to provide a coherent view that explores the interrelationships between the various components of the programme.

PROGRAMME LEARNING OUTCOMES

Knowledge and understanding
-State-of- the-art knowledge in petroleum refining and petrochemical processing, in terms of the technologies of processes that comprise a modern refinery and petrochemicals complex
-The principles for analysing and improving the profitability of refining and petrochemicals processing
-General Safety, health, and environment (SHE) principles on a refinery and petrochemicals complex
-Methods and systems for ensuring safe and reliable design and operation of process units
-State-of- the-art knowledge in process systems engineering methods, in the areas of: modelling and simulation of process systems, mathematical optimization and decision making, process systems design and process and energy integration
-Advanced level of understanding in technical topics of preference, in one or more of the following aspects: petroleum exploration and production, economics of the energy sector, sustainable and renewable systems, supply chain management

Intellectual / cognitive skills
-The programme aims to strengthen cognitive skills of the students, particularly in the aspects of problem definition, knowledge and information acquiring, synthesis, and creativity, as collectively demonstrable through the successful completion of the research dissertation.
-Select, define and focus upon an issue at an appropriate level
-Collect and digest knowledge and information selectively and independently to support a particular scientific or engineering enquiry
-Develop and apply relevant and sound methodologies for analysing the issue, developing solutions, recommendations and logical conclusions, and for evaluating the results of own or other’s work

Professional practical skills
-Apply knowledge of the operation of refineries to analyze and to improve the profitability of refining and petrochemical processing
-Apply relevant principles, methods, and tools to improve the safety and operation integrity of refineries
-Apply systems engineering methods such as modelling, simulation, optimization, and energy integration to improve the design of petroleum refining units and systems

Key / transferable skills
-The programme aims to strengthen a range of transferable skills that are relevant to the needs of existing and future professionals in knowledge intensive industries irrespective of their sector of operation.
-Preparation and delivery of communication and presentation
-Report and essay writing
-Use of general and professional computing tools
-Collaborative working with team members
-Organizing and planning of work
-Research into new areas, particularly in the aspect of literature review and skills acquisition

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 programme integrates important, current and employer relevant themes and enables you to acquire knowledge and skills across a wide range of appropriate topics for petroleum, oil and gas technology, with an emphasis upon management. Read more
This programme integrates important, current and employer relevant themes and enables you to acquire knowledge and skills across a wide range of appropriate topics for petroleum, oil and gas technology, with an emphasis upon management.

This MSc is taught by lectures, practical experiments and design projects, supported by problem classes and tutorials. Laboratory-based work is an important part of the programme and takes a number of forms, from experimental investigation carried out individually over a short period of time, to extended group project work in which teamwork, project management and communication skills are as important as technical proficiency.

Core modules

• Energy Technologies
• Engineering Management for Process Industries
• Industrial Management, Research Skills and Project Planning
• Sustainable Business: Principles and Practice of Green Management
• Petroleum and Petrochemical Engineering
• Petroleum, Oil and Gas: Chemical Engineering Management MSc Project

Optional modules

• Advanced Process Simulation and Modelling Techniques
• Qualitative/Quantitative Research in Business and Management

The focus on technology, its applications, uses and refinements, are novel features of this programme.

Our campus is ideally situated in the Humber region, which is home to more than 350 companies involved in the chemical and allied industries including ConocoPhillips, BP Chemicals, Total, Reckitt Benckiser and Smith and Nephew.

As a student on the MSc, you will gain access to some of the best facilities in the UK including the Centre for Assessment of Technical Competency (CATCH). This £8 million centre provides a fantastic opportunity to experience realistic equipment and operating procedures.

We work closely with industry to ensure the standard of our teaching keeps pace with advances in the profession. For this reason, our engineering graduates are highly soughtafter by all employment sectors.

The School’s continued development of chemical engineering-related provision has the support of the chemical and process engineering’s professional body, the IChemE.

Research areas

The School focuses on the application of research to solve real-world problems by taking a multi-disciplinary approach. Specialist research activities in a broad range of chemical engineering topics are currently being undertaken and include: process simulation; energy utilisation; carbon capture and sequestration; oil and gas engineering; heat transfer and fluid dynamics.

Read less
Designed in close collaboration with industry, this programme takes a theoretical and a practical approach to ensure it meets the requirements of potential employers. Read more
Designed in close collaboration with industry, this programme takes a theoretical and a practical approach to ensure it meets the requirements of potential employers.

The interdisciplinary nature of the MSc makes it suitable for applicants from a wide variety of engineering and scientific backgrounds. It is appropriate for you if you wish to enter, or enhance, a technical career in the petroleum, oil and gas industry.

This MSc is studied full-time over one year starting in September and comprises two semesters of taught modules followed by an individual research project.

This programme integrates important, current and employer relevant themes and enables students to acquire knowledge and skills across a wide range of appropriate topics for petroleum, oil and gas technology, with an emphasis upon chemical engineering applications.

This MSc is taught by lectures, practical experiments and design projects, supported by problem classes and tutorials. Laboratory-based work is an important part of the programme and takes a number of forms, from experimental investigation carried out individually in a short period of time, to extended group project work in which teamwork, project management and communication skills are as important as technical proficiency.

Core modules

• Energy Technologies
• Advanced Process Safety and Control
• Industrial Management, Research Skills and Project Planning
• Advanced Process Simulation and Modelling Techniques
• Petroleum and Petrochemical Engineering
• Chemometrics for Engineers
• Petroleum, Oil and Gas: Chemical Engineering Technologies MSc Project

The focus on technology, its applications, uses and refinements, are novel features of this programme.

Our campus is ideally situated in the Humber region, which is home to more than 350 companies involved in the chemical and allied industries including ConocoPhillips, BP Chemicals, Total, Reckitt Benckiser and Smith and Nephew.

As a student on the MSc, you will gain access to some of the best facilities in the UK including the Centre for Assessment of Technical Competency (CATCH). This £8 million centre provides a fantastic opportunity to experience realistic equipment and operating procedures.

We work closely with industry to ensure the standard of our teaching keeps pace with advances in the profession. For this reason, our engineering graduates are highly soughtafter by all employment sectors.

The School’s continued development of chemical engineering-related provision has the support of the chemical and process engineering’s professional body, the IChemE.

Research areas

The School focuses on the application of research to solve real-world problems by taking a multi-disciplinary approach. Specialist research activities in a broad range of chemical engineering topics are currently being undertaken and include: process simulation; energy utilisation; carbon capture and sequestration; oil and gas engineering; heat transfer and fluid dynamics.

Read less
Do you train healthcare providers or organise systems to improve patient safety? This one year masters programme will enable you to apply innovative educational methods and processes to improve patient outcomes. Read more
Do you train healthcare providers or organise systems to improve patient safety? This one year masters programme will enable you to apply innovative educational methods and processes to improve patient outcomes. Explore an in-depth range of simulation-based learning techniques and be equipped with the skills required to plan and conduct your dissertation. Be primed with the advanced knowledge and understanding to confidently lead improvements in the quality of patient safety in your workplace.

Key features

-Explore a range of simulation-based learning methods that can improve quality of patient care. Recent national reports have emphasised the need for widened access to simulation training and the recognition of person-level and system-level human factors in improving patient safety.
-Develop an understanding of the factors involved in quality improvement strategies and their evaluation using outcomes related to patient safety.
-Undertake a critical study of education and expert practice, change management and innovation.
-Equip yourself with the skills to plan and conduct a full masters dissertation.
-Get a variety of hands-on experience – the Simulation and Enhanced Learning module will be delivered at the Horizon Centre, a new innovation, education and research facility at Torbay Hospital. The remaining taught modules will be delivered in the John Bull Building, Plymouth Science Park. Find out more about your teaching locations.
-Advance your knowledge, understanding and skills in patient safety and quality improvement and have the opportunities to apply these skills in the clinical environment.
-Take advantage of our experienced teaching staff drawn from experts in the Plymouth and Torbay NHS trusts and the University, as well as from the higher education sector in the South West region and beyond.
-Benefit from flexible learning – there are a number of continuing professional development (CPD) opportunities relating to this programme where a single module or specific days within a module may be taken independently.
-Graduate with the skills required to implement simulation effectively into educational programmes, and develop and evaluate evidence-based patient safety strategies in organisations.
-You’ll be supported by a PUPSMD staff member and can attend seminars of the medical education research group CAMERA.

Course details

You’ll explore a range of simulation-based learning methods that can improve patient safety and quality of care through enhanced learning. Advance your knowledge, understanding and skills in patient safety and the application of these to your own workplace. You’ll be introduced to the role of human factors and develop a critical understanding of the current state of patient safety within healthcare and examine strategies to improve it. You’ll be provided with the knowledge and skills associated with the project design, development and knowledge transfer process. You’ll also explore the physical and psychological links between organisations, employees and their work environment and how the concept of human factors influences the way we work. The use of simulation for training and assessment of human factors will be integral to the module.

Core modules
-DIS731 Dissertation
-SIM714 Patient Safety and Quality Improvement
-PDD721 Project Design, Development and Knowledge Transfer
-SIM711 Simulation and Enhanced Learning
-SIM715 Human Factors in Healthcare

Every postgraduate taught course has a detailed programme specification document describing the programme aims, the programme structure, the teaching and learning methods, the learning outcomes and the rules of assessment.

For more information on the part time version of this course, view the web-page: https://www.plymouth.ac.uk/courses/postgraduate/msc-simulation-and-patient-safety

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This Postgraduate Certificate in Simulation and Clinical Learning has been designed for a range of health professionals (medical doctors, dentists, nurses and allied health professionals), clinical educators and healthcare managers who wish to develop specialist knowledge, skills and understanding of simulation as a modality for teaching and supporting learning and assessment. Read more
This Postgraduate Certificate in Simulation and Clinical Learning has been designed for a range of health professionals (medical doctors, dentists, nurses and allied health professionals), clinical educators and healthcare managers who wish to develop specialist knowledge, skills and understanding of simulation as a modality for teaching and supporting learning and assessment. It will equip you with a critical understanding of how simulation can be deployed to enhance teaching, learning and assessment in the field of healthcare.

Simulation can be defined as emulating a real life situation in a controlled (non-real) environment, to safely provide a life-like experience. This creates the opportunity to act, reflect and obtain feedback to assist in achieving competence and progression towards expert level through deliberate and repeated practice in an ascending learning spiral.

The programme will be run on a multi-professional basis, allowing practitioners, managers and clinical educators from different professions and locations to share their knowledge, experience and skills. You will systematically and creatively analyse the complexities of clinical education and explore and articulate opportunities for developing simulation in your own practice.

What will I study?

The course will focus on furthering your understanding of simulation as a teaching, learning and assessment modality for clinicians.

In the first two modules, underpinning theory will be explored in relation to simulation, and the range of different potential types and uses of simulation will be examined in relation to existing literature.

You will then have the opportunity to specialise in the particular area of clinical education most suited to your own situation and professional interests. Pathways are available in Curriculum Design, Educational Leadership, Educational Supervision, Technology Enhanced Learning and Improving Practice.

How will I study?

The course is delivered through online blended learning, using the University’s Virtual Learning Environment (VLE), with streamlined access to online reading materials, many of which have been specially optimised for use with mobile devices. It is designed to be ‘step on, step off’, offering flexibility for participants to study in a single year or over a maximum three-year period.

The online learning is blended with a small number of face-to-face workshops, typically up to three per module. Attendance at the face-to-face sessions is highly recommended but, due to the flexibility of the programme, it is not compulsory.

Edge Hill University is the usual location for face-to-face sessions. The campus provides a modern and stimulating environment for study and is equipped with state-of-the-art teaching and learning facilities. The VLE is used to deliver the online elements of the programme.

How will I be assessed?

There are no examinations. A range of assessment strategies are employed in this programme including online tasks, critical reflection on practice, assignments, evaluative reports, case studies, peer observation of teaching, the design of learning activities and the creation of portfolios. You will be supported by your academic tutors with academic skills practice and ‘formative feedback’ on work-in-progress. You will be expected to write approximately 4,000 words (or equivalent) for each module.

Who will be teaching me?

The academic team comprises highly experienced tutors from Edge Hill University, as well as a Visiting Professor and Emeritus Professor. Many of the team are research active in the fields of technology enhanced learning and clinical education and some are also University Teaching and Learning Fellows or SOLSTICE Fellows, with an extensive publication record.

Some of the academic tutors are, or have been, practising clinicians who have specialised in clinical education whilst others are experienced educationalists from a range of backgrounds. The team is further enhanced by an experienced learning technologist and there is guest input from clinical experts and practitioners.

What are my career prospects?

This PGCert will provide specialist knowledge that would be useful for any career in the field of healthcare that involves the support of learning and assessment in practice. In addition, the programme will enable you to develop the skills of critical analysis, critical reflection and the evaluation of research evidence commensurate with postgraduate study.

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This programme is idea for graduates from engineering, science or other relevant backgrounds and who have an interest in pursuing a successful career in research, technological change and the commercialisation of renewable-energy systems. Read more
This programme is idea for graduates from engineering, science or other relevant backgrounds and who have an interest in pursuing a successful career in research, technological change and the commercialisation of renewable-energy systems.

This programme will give you opportunities to learn about major renewable-energy technologies, energy-sector economics, supply-chain management and sustainable development.

PROGRAMME OVERVIEW

Created in the context of the rapid advancement of the renewable-energy industry, this Masters programme investigates both renewable energy and systems technologies.

It is designed to build your competence and confidence in the R&D and engineering tasks that are demanded of scientific engineers in the renewable and sustainable-development sector.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year. It consists of eight taught modules and a dissertation. 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.
-Optimisation and Decision-Making
-Process Modelling and Simulation
-Technology, Business & Research Seminars
-Renewable Energy Technologies
-Refinery and Petrochemical Process
-Solar Energy Technology
-Advanced Process Control
-Energy Economics and Technology
-Process Systems Design
-Biomass Processing Technology
-Wind Energy Technology
-Process and Energy Integration
-Knowledge-based Systems and Artificial Intelligence
-Supply Chain Management
-Introduction to Petroleum Production
-Process Safety and Operation Integrity
-Economics of International Oil & Gas
-Dissertation

FACILITIES, EQUIPMENT AND ACADEMIC SUPPORT

Modules related to the different groups are taught by a total of six full-time members of staff and a number of visiting lecturers.

As part of their learning experience, students have at their disposal a wide range of relevant software needed to support the programme material dissertation projects. In recent years, this work included the design of various knowledge-based and business systems on the internet, the application of optimisation algorithms, and semantic web applications.

Numerous laboratory facilities across the Faculty and the University are also available for those opting for technology-based projects, such as the process engineering facility, a control and robotics facility and signal processing labs.

The work related to the MSc dissertation can often be carried out in parallel with, and in support of, ongoing research. In the past, several graduates have carried on their MSc research to a PhD programme.

CAREER PROSPECTS

Engineers and scientists are increasingly expected to have skills in information systems engineering and decision-support systems alongside their main technical and/or scientific expertise.

Graduates of this programme will be well prepared to help technology-intensive organisations make important decisions in view of vast amounts of information by adopting, combining, implementing and executing the right technologies.

EDUCATIONAL AIMS OF THE PROGRAMME

This programme investigates both renewable energy and systems technologies in order to produce scientific researchers and engineers who are competent in the R&D and engineering tasks applicable to the renewable energy and sustainable development sectors.

Its primary aims lie in developing a global understanding of the major types of renewable energy technologies, in-depth knowledge of the technology for biomass-based renewable energy, and knowledge and skills in systems modelling and optimisation.

A balanced curriculum will be provided with a core of renewable energy and systems engineering modules supplemented by a flexible element by way of elective modules that permit students to pursue an element of specialisation relevant to their backgrounds, interests and/or career aspirations.

An integrated approach is taken so as to provide a coherent view that explores the interrelationships between the various components of the programme.

PROGRAMME LEARNING OUTCOMES

Knowledge and understanding
-State-of- the-art knowledge in renewable energy technologies, in terms of: the sources, technologies, systems, performance, and applications of all the major types of renewable energy; approaches to the assessment of renewable energy technologies; the processes, equipment, products, and integration opportunities of biomass-based manufacturing
-State-of- the-art knowledge in process systems engineering methods, in the areas of: modelling and simulation of process systems; mathematical optimization and decision making; process systems design
-Advanced level of understanding in technical topics of preference, in one or more of the following aspects: process and energy integration, economics of the energy sector, sustainable development, supply chain management

Intellectual / cognitive skills
-Select, define and focus upon an issue at an appropriate level
-Collect and digest knowledge and information selectively and independently to support a particular scientific or engineering enquiry
-Develop and apply relevant and sound methodologies for analysing the issue, developing solutions, recommendations and logical conclusions, and for evaluating the results of own or other’s work

Professional practical skills
-Assess the available renewable energy systems
-Design and select appropriate collection and storage, and optimise and evaluate system design
-Apply generic systems engineering methods such as modelling, simulation, and optimization to facilitate the assessment and development of renewable energy technologies and systems

Key / transferable skills
-Preparation and delivery of communication and presentation
-Report and essay writing
-Use of general and professional computing tools
-Collaborative working with team members
-Organizing and planning of work
-Research into new areas, particularly in the aspect of literature review and skills acquisition

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 course offers students a grounding in modelling, simulation and optimisation for the process industries, while helping them to strengthen their understanding of chemical engineering. Read more
This course offers students a grounding in modelling, simulation and optimisation for the process industries, while helping them to strengthen their understanding of chemical engineering. Students take a minimum of four systems engineering modules, six "free" modules (up to two management courses), follow the professional skills workshops and join the Process Systems Engineering research focus area for a year-long research project. This course is ideal for students wishing to become fluent in the use of techniques and tools for computer-aided decision-making.

The programme aims to:
• produce graduates equipped to pursue careers in Process Systems Engineering, in industry, the public sector and non-governmental organisations, or to enter Ph.D. programmes;
• provide the basis for the understanding of the development and key achievements of the major areas of Process Systems Engineering and in Chemical Engineering topics of interest;
• develop an understanding of how this knowledge may be applied in practice in an economic and environmentally friendly fashion;
• foster the acquisition and implementation of broad research and analytical skills both general and related to Process Systems Engineering;
• attract highly motivated students, both from within the UK and from overseas;
• develop new areas of teaching in response to the advance of scholarship and the needs of vocational training;
• offer students with industrial experience the possibility to gain a deeper fundamental grounding.

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The MSc in Advanced Process Integration and Design started in the Department of Chemical Engineering (UMIST) over twenty years ago. Read more
The MSc in Advanced Process Integration and Design started in the Department of Chemical Engineering (UMIST) over twenty years ago. The programme was a result of emerging research from the Centre for Process Integration, initially focused on energy efficiency, but expanded to include efficient use of raw materials and emissions reduction. Much of the content of the course stems from research related to energy production, including oil and gas processing.

The MSc in Advanced Process Integration and Design aims to enable students with a prior qualification in chemical engineering to acquire a deep and systematic conceptual understanding of the principles of process design and integration in relation to the petroleum, gas and chemicals sectors of the process industries.

Overview of course structure and content
In the first trimester, all students take course units on energy systems, utility systems and computer aided process design. Energy Systems develops systematic methods for designing heat recovery systems, while Utility Systems focuses on provision of heat and power in the process industries. Computer Aided Process Design develops skills for modelling and optimisation of chemical processes.

In the second trimester, the students choose three elective units from a range covering reaction systems, distillation systems, distributed and renewable energy systems, biorefining, and oil and gas processing. These units focus on design, optimisation and integration of process technologies and their associated heat and power supply systems.

In two research-related units, students develop their research skills and prepare a proposal for their research project. These units develop students skills in critical assessment of research literature, group work, written and oral communication, time management and research planning.

Students then carry out the research project during the third trimester. In these projects, students apply their knowledge and skills in process design and integration to investigate a wide range of process technologies and design methodologies. Recent projects have addressed modelling, assessment and optimisation of petroleum refinery hydrotreating processes, crude oil distillation systems, power plants, waste heat recovery systems, refrigeration cycles with mixed refrigerants, heat recovery steam generators, biorefining and biocatalytic processes and waste-to-energy technologies.

The course also aims to develop students' skills in implementing engineering models, optimisation and process simulation, in the context of chemical processes, using bespoke and commercially available software.

Industrial relevance of the course
A key feature of the course is the applicability and relevance of the learning to the process industries. The programme is underpinned by research activities in the Centre for Process Integration within the School. This research focuses on energy efficiency, the efficient use of raw materials, the reduction of emissions reduction and operability in the process industries. Much of this research has been supported financially by the Process Integration Research Consortium for over 30 years. Course units are updated regularly to reflect emerging research and design technologies developed at the University of Manchester and also from other research groups worldwide contributing to the field.

The research results have been transferred to industry via research communications, training and software leading to successful industrial application of the new methodologies. The Research Consortium continues to support research in process integration and design in Manchester, identifying industrial needs and challenges requiring further research and investigation and providing valuable feedback on practical application of the methodologies. In addition, the Centre for Process Integration has long history of delivering material in the form of continuing professional development courses, for example in Japan, China, Malaysia, Australia, India, Saudi Arabia, Libya, Europe, the United States, Brazil and Colombia.

Career opportunities

The MSc course in Advanced Process Design and Integration typically attracts 40 students; our graduates have found employment with major international oil and petrochemical companies (e.g. Shell, BP, Reliance and Petrobras and Saudi Aramco), chemical and process companies (e.g. Air Products), engineering, consultancy and software companies (e.g. Jacobs and Aspen Tech) and academia.

Accrediting organisations

This programme is accredited by the IChemE (Institution of Chemical Engineers).

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Student research degrees in Metallic Materials are based within a vibrant research group, which is one of the largest in the UK. The research encompasses all aspects of metals alloys and composites, including their design, processing, forming, joining and performance. Read more
Student research degrees in Metallic Materials are based within a vibrant research group, which is one of the largest in the UK. The research encompasses all aspects of metals alloys and composites, including their design, processing, forming, joining and performance.

Research Focus
The research extends from fundamental science, and the ‘blue skies’ development of novel technologies and techniques, to the very applied, with the aim of improving our understanding of the basic governing principles, process simulation and physical modelling. While our research is broad ranging, we focus on light alloys for aerospace and transport applications, high-temperature materials for aeroengines and power generation, and metal composites, as well as the failure of metallic materials, their environmental degradation and surface treatment. The research is supported by state of the art equipment for materials characterisation, testing, simulation and processing.

Examples of recent student PhD projects include; Microstructure Modelling for Friction Stir Welding, Laser Surface treatment of Aerospace Alloys, Advanced Strain Mapping for Structural Integrity application, Dynamic Grain Growth in Super Plastic Forming, Dynamics and Morphology of Stress Corrosion Cracking Using 3D X-ray Tomography, and Laser Depositioning of Nickel Base Superalloys.

Industry links
We have strong links with industry and the funding councils and sponsorship from global companies, including; Airbus, Alcan, Alcoa, British Energy, Rolls Royce, BNF and Jaguar. Major initiatives include the £6M EPSRC-Manchester Portfolio Partnership in Light Alloys for Environmentally Sustainable Transport and the Materials Performance Centre, a research alliance established with Nexia Solutions (supported by the NDA) in 2002, and partnered with British Energy, Serco Assurance, EDF and Westinghouse.

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Student research degrees in Metallic Materials are based within a vibrant research group, which is one of the largest in the UK. The research encompasses all aspects of metals alloys and composites, including their design, processing, forming, joining and performance. Read more
Student research degrees in Metallic Materials are based within a vibrant research group, which is one of the largest in the UK. The research encompasses all aspects of metals alloys and composites, including their design, processing, forming, joining and performance.

Research Focus
The research extends from fundamental science, and the ‘blue skies’ development of novel technologies and techniques, to the very applied, with the aim of improving our understanding of the basic governing principles, process simulation and physical modelling. While our research is broad ranging, we focus on light alloys for aerospace and transport applications, high-temperature materials for aeroengines and power generation, and metal composites, as well as the failure of metallic materials, their environmental degradation and surface treatment. The research is supported by state of the art equipment for materials characterisation, testing, simulation and processing.

Examples of recent student PhD projects include; Microstructure Modelling for Friction Stir Welding, Laser Surface treatment of Aerospace Alloys, Advanced Strain Mapping for Structural Integrity application, Dynamic Grain Growth in Super Plastic Forming, Dynamics and Morphology of Stress Corrosion Cracking Using 3D X-ray Tomography, and Laser Depositioning of Nickel Base Superalloys.

Industry links
We have strong links with industry and the funding councils and sponsorship from global companies, including; Airbus, Alcan, Alcoa, British Energy, Rolls Royce, BNF and Jaguar. Major initiatives include the £6M EPSRC-Manchester Portfolio Partnership in Light Alloys for Environmentally Sustainable Transport and the Materials Performance Centre, a research alliance established with Nexia Solutions (supported by the NDA) in 2002, and partnered with British Energy, Serco Assurance, EDF and Westinghouse.

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WHAT YOU WILL GAIN. - Skills and know-how in the latest technologies in all aspects of plant engineering. - Guidance from practicing plant engineering experts in the field. Read more
WHAT YOU WILL GAIN:

- Skills and know-how in the latest technologies in all aspects of plant engineering
- Guidance from practicing plant engineering experts in the field
- Knowledge from the extensive experience of instructors, rather than from clinical information gained from books and college
- Improved career prospects and income
- An EIT Advanced Diploma of Plant Engineering

Start Date: September 18, 2017.

INTRODUCTION

This practical course avoids over emphasis on theory. This is rarely needed in the real industrial world where time is short and immediate results are required. Hard-hitting and useful know-how, are needed as minimum requirements. The instructors presenting this advanced diploma are highly experienced engineers from industry who have many years of real-life experience as Plant Engineers. The format of presentation - live, interactive distance learning with the use of remote labs means that you can hit the ground running and be of immediate benefit to your company or future employer.

WHO SHOULD ATTEND?

Anyone who wants to gain solid knowledge of the key elements of Plant Engineering to improve their work skills and to further their job prospects:

- Electrical Engineers who need an overall Plant Engineering appreciation
- Electricians
- Maintenance Engineers and Supervisors
- Automation and Process Engineers
- Design Engineers
- Project Managers
- Consulting Engineers
- Production Managers
- Chemical and Mechanical Engineers
- Instrument and Process Control Technicians

Even those who are highly experienced in Plant Engineering may find it useful to follow some of the topics to gain know-how in a very concentrated but practical format.

COURSE STRUCTURE

The course follows six engineering threads to provide you with maximum practical coverage in the field of Plant Engineering:

- Overview and where the Plant Engineer fits into the 21st century production sphere
- Engineering technologies in detail
- Skills for project, process, environmental and energy management
- Maintenance management
- Safety management; with corresponding legal knowledge
- Other necessary skills to master

The course is composed 19 modules. These modules cover a range of aspects to provide you with maximum practical coverage in the field of Plant Engineering.

The modules are:

- Introduction to Plant Engineering
- Plant Operations and Facility Management
- Electrical Equipment and Technology
- Pressure Vessels and Boilers
- Fundamentals of Professional Engineering
- Mechanical Equipment and Technology
- Fluid Power Systems and Components
- Pumps and Seals
- Thermodynamics, Compressors, Fans and Blowers
- Process Plant Layout and Piping Design
- Heating, Ventilation and Air Conditioning
- Noise and Vibration
- Structural and Civil Engineering Concepts
- Process Management
- Energy Management
- Instrumentation and Control Engineering
- Maintenance Management
- Environmental Engineering
- Safety Management

PRESENTATION FORMAT

The programme features real-world applications and uses a multi-pronged approach involving interactive on-line webinars, simulation software and self-study assignments with a mentor on call. The course consists of 72 topics delivered over a period of 18 months. Presentations and group discussions will be conducted using a live, interactive software system. For each topic you will have an initial reading assignment (which will be delivered to you in electronic format in advance of the online presentations). There will be coursework or problems to be submitted and in some cases there will be practical exercises, using simulation software and remote labs that you can easily do from your home or office. You will have ongoing support from the instructors via phone, fax and e-mail.

LIVE WEBINARS

The webinar schedule is not put together until after registrations close. The reason for this is that the program is promoted globally and we often have participants from several time zones. When you enrol you will receive a questionnaire which will help us determine your availability. When all questionnaires are returned we create a schedule which will endeavour to meet everyone’s requirements. Each webinar runs 2 or 3 times during each presentation day and we try our best to ensure that at least one session falls into your requested time frames. This is not always possible, however, due to the range of locations of both presenters and students. If you are unable to attend the webinars scheduled, we do have some options available. Contact the EIT for more details.

PRACTICAL EXERCISES AND REMOTE LABORATORIES

As part of the groundbreaking new way of teaching, we will be using a series of remote laboratories (labs) and simulation software, to facilitate your learning and to test the knowledge you gain during the course. These involve complete working labs set up at various locations of the world into which you will be able to log and proceed through the various practical sessions. These will be supplemented by simulation software, running either remotely or on your computer, to ensure you gain the requisite handson experience. No one can learn much solely from lectures, the labs and simulation software are designed to increase the absorption of the materials and to give you a practical orientation of the learning experience. All this will give you a solid, practical exposure to the key principles covered in the course and will Practical Exercises and Remote Laboratories ensure that you obtain maximum benefit from the course to succeed in your future career in Industrial Automation.

COURSE FEES

What are the fees for my country?

The Engineering Institute of Technology (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 customised to your individual circumstances.

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

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This programme is aimed at anyone interested in learning more about the design and operation of low energy buildings with the added attraction of three modules dedicated to computer modelling of building performance – an essential skill for anyone wishing to work in today’s rapidly changing world of building engineering consultancy. Read more
This programme is aimed at anyone interested in learning more about the design and operation of low energy buildings with the added attraction of three modules dedicated to computer modelling of building performance – an essential skill for anyone wishing to work in today’s rapidly changing world of building engineering consultancy.

Modules are taught by world-leading experts in the field who have designed some of the world’s most innovative low energy buildings. These design experiences provide unique case study material which students find exciting and invaluable for their own research and design work.

The programme is accredited for further learning for CEng and professional membership by CIBSE and the Energy Institute and benefits from its links with the Royal Academy of Engineering Centre of Excellence in Sustainable Building Design.

The course attracts students from all over the world, including countries such as Greece, Iran, China, France, Germany and Colombia. This is attractive to potential employers who often have international offices around the world.

Key Facts

- An outstanding place to study. The School of Civil and Building Engineering is ranked 2nd in the UK for Building in the Times Good University Guide 2015

- Research-led teaching from international experts. 75% of the School’s research was rated as world-leading or internationally excellent in the latest Government Research Excellence Framework.

- The programme is accredited by the two main institutions representing energy and buildings – the Chartered Institution of Building Services Engineers and the Energy Institute. On successful completion of the course, students are deemed to meet the education requirements for both institutions and their applications can be endorsed by course tutors.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/civil/low-carbon-building-design/

Programme modules

- Building Energy Consumption [70% exam, 10 credits]
The aim of this module is for the student to understand the impact that climate, people, equipment selection and design have on energy consumption on a range of building sizes from domestic to large commercial.

- Renewable Energy and Low Carbon Technologies [70% exam, 15 credits]
The aims of this module are for the student to understand the principles of renewable energy and low carbon technologies and their integration into buildings, and to be given a perspective on the potential benefits and applications of these technologies.

- Building Control & Commissioning [70% exam, 10 credits]
The aims of this module are for the student to understand the application of automatic control in energy monitoring and commissioning and to examine the control problems in buildings and develop control strategies that will improve thermal comfort and building energy use.

- Concept Design [0% exam, 15 credits]
The aims of this module are for the student to be introduced to the process within which buildings are conceived and designed by undertaking the architecture design of a major building using multi-disciplinary input. Students will develop team skills through working in design groups to generate schematic concepts before developing the best. They will apply previous knowledge of building services and low carbon design in the selection process and carry out performance analysis. Students will work with 3D architectural and 3D mechanical, electrical and plumbing (MEP) systems within BIM software to further develop their concepts.

- Low Carbon Building Design [50% exam, 15 credits]
The module aims to introduce the principles of low and zero carbon building with special attention to the process of design and decision-making.

- Advanced Thermal Modelling [50% exam, 15 credits]
The aims of this module are for the student to understand the principles of building thermal modelling and HVAC plant simulation, and be given a perspective on the applications of these techniques to the design process.

- Advanced Airflow Modelling [50% exam, 15 credits]
The aims of this module are for the student to understand the principles of building airflow and ventilation modelling with respect to comfort and energy efficiency, and be given a perspective on the applications of these techniques to the design process.

- Advanced Lighting Modelling [50% exam, 15 credits]
The aims of this module are for the student to understand the principles of lighting modelling in buildings with respect to comfort and energy efficiency, and be given a perspective on the application of these techniques to the design process.

- Research Project [0% exam, 60 credits]
The aim of this module is to provide the student with experience of the process and methodology of research by defining and studying (on an individual basis) a complex problem in a specialised area relating to Building Energy

- Research Methods in Building Performance [0% exam, 10 credits]
The aims of this module are for the student to become familiar with and comprehend the wide range of research methods and skills needed to investigate, understand and communicate building performance.

Facilities

All masters students have access to a wide range of building simulation codes which include commercial software, as well as bespoke codes developed in-house. Students can run these codes on their personal laptops or access any one of our computer laboratories, including access to our recently commissioned 2000-node high performance computer cluster.

One of our key strengths at Loughborough is our experimental facilities which enable us to validate computer models. Our masters students have access to a vast range of experimental facilities, some of which are used during the taught modules and all of which are available for use by students during their research dissertations.

These include: a fully controllable environmental chamber; sophisticated thermal and breathing manikins; an indoor solar simulator; a 'darkroom' facility to carry out optical and high dynamic range measurements; and full-scale houses for pressure testing and studying innovative heating and control strategies. A recent investment of £360k was made to purchase an extensive array of monitoring and measuring equipment for use during field studies.

How you will learn

You will learn through a carefully balanced combination of lectures, in-class guided workshops, hands-on computer modelling, field measurements and independent research. Students have access to a wide range of air flow, thermal and daylight modelling software as well as extensive laboratory facilities. Following nine taught modules, students pursue a research dissertation of their choice which draws on the skills developed during the taught modules.

Students are assessed by a combination of traditional written exams, coursework and assignments. This split is typically 70/30 (exam/coursework) or 50/50, although some modules, such as research methods and concept design are assessed entirely based on coursework which comprises individual presentations and group work.

Careers and further study

Previous students have gone on to work for leading consulting engineering companies such as Arup, Pick Everad, Hoare Lea, Hulley and Kirkwood and SE Controls. Some of these companies offer work placements for students to undertake their research dissertations. Many visit the university to deliver lectures to our MSc students providing ideal opportunities for students to discuss employment opportunities.

Accreditation

The programme is accredited for further learning for CEng and professional membership by the CIBSE and Energy Institute.
The 'SE Controls prize for best overall performance' is awarded to the student graduating from this course with the highest overall mark. This presentation is made on graduation day.

Scholarships

The University offers over 100 scholarships each year to new self-financing full-time international students who are permanently resident in a county outside the European Union. These Scholarships are to the value of 25% of the programme tuition fee and that value will be credited to the student’s tuition fee account.
You can apply for a scholarship once you have received an offer for a place on this programme.

Why choose civil engineering at Loughborough?

As one of four Royal Academy of Engineering designated Centres of Excellence in Sustainable Building Design, the School of Civil and Building Engineering is one of the largest of its type in the UK and holds together a thriving community of over 60 academic staff, 40 technical and clerical support staff and over 240 active researchers that include Fellows, Associates, Assistants, Engineers and Doctoral Students.

Our world-class teaching and research are integrated to support the technical and commercial needs of both industry and society. A key part of our ethos is our extensive links with industry resulting in our graduates being extremely sought after by industry and commerce world-wide,

- Postgraduate programmes
The School offers a focussed suite of post graduate programmes aligned to meet the needs of industry and fully accredited by the relevant professional institutions. Consequently, our record of graduate employment is second to none. Our programmes also have a long track record of delivering high quality, research-led education. Indeed, some of our programmes have been responding to the needs of industry and producing high quality graduates for over 40 years.

Currently, our suite of Masters programmes seeks to draw upon our cutting edge research and broad base knowledge of within the areas of contemporary construction management, project management, infrastructure management, building engineering, building modelling, building energy demand and waste and water engineering. The programmes are designed to respond to contemporary issues in the field such as sustainable construction, low carbon building, low energy services, project complexity, socio-technical systems and socio-economic concerns.

- Research
Drawing from our excellent record in attracting research funds (currently standing at over £19M), the focal point of the School is innovative, industry-relevant research. This continues to nurture and refresh our long history of working closely with industrial partners on novel collaborative research and informs our ongoing innovative teaching and extensive enterprise activities. This is further complemented by our outstanding record of doctoral supervision which has provided, on average, a PhD graduate from the School every two weeks.

- Career Prospects
Independent surveys continue to show that industry has the highest regard for our graduates. Over 90% were in employment and/or further study six months after graduating. Recent independent surveys of major employers have also consistently rated the School at the top nationally for civil engineering and construction graduates.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/civil/low-carbon-building-design/

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