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Masters Degrees (Process Systems Engineering)

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Process systems engineering deals with the design, operation, optimisation and control of all kinds of chemical, physical, and biological processes through the use of systematic computer-aided approaches. Read more

Process systems engineering deals with the design, operation, optimisation and control of all kinds of chemical, physical, and biological processes through the use of systematic computer-aided approaches. Its major challenges are the development of concepts, methodologies and models for the prediction of performance and for decision-making for an engineered system.

Who is it for?

Suitable for engineering and applied science graduates who wish to embark on successful careers as process systems engineering professionals. 

The course equips graduates and practising engineers with an in-depth knowledge of the fundamentals of process systems and an excellent competency in the use of state-of-the-art approaches to deal with the major operational and design issues of the modern process industry. The course provides up-to-date technical knowledge and skills required for achieving the best management, design, control and operation of efficient process systems. 

Why this course?

Process systems engineering constitutes an interdisciplinary research area within the chemical engineering discipline. It focuses on the use of experimental techniques and systematic computer-aided methodologies for the design, operation, optimisation and control of chemical, physical, and biological processes, e.g. from chemical and petrochemical processes to pharmaceutical and food processes. 

A distinguished feature of this course is that it is not directed exclusively at chemical engineering graduates. Throughout the years, the course has evolved from discussions with industrial advisory panels, employers, sponsors and previous students. The content of the study programme is updated regularly to reflect changes arising from technical advances, economic factors and changes in legislation, regulations and standards.

By completing this course, a diligent student will be able to: 

  • Evaluate the technical, environmental and economic issues involved in the design and operation of process plants and the current practice in process industries.
  • Apply effectively the knowledge gained to the design, operation, optimisation and control of process systems via proper methodologies and relevant software.
  • Apply independent learning, especially via the effective use of information retrieval systems and a competent and professional approach to solving problems of industrial process systems.
  • Apply and critically evaluate key technical management principles, including project management, people management, technology marketing, product development and finance.
  • Apply advanced approaches and use effectively related tools in more specialised subjects related to process industries (for example risk management, biofuels or CFD tools).
  • Integrate knowledge, understanding and skills from the taught modules in a real-life situation to address problems faced by industrial clients; creating new problem diagnoses, designs, or system insights; and communicating findings in a professional manner in written, oral and visual forms.
  • Define a research question, develop aim(s) and objectives, select and execute a methodology, analyse data, evaluate findings critically and draw justifiable conclusions, demonstrating self-direction and originality of thought.
  • To communicate his/her individual research via a thesis and in an oral presentation in a style suitable for academic and professional audiences.

Accreditation

This MSc degree is accredited by Institution of Mechanical Engineers (IMechE).

Course details

The taught programme for the MSc in Process Systems Engineering is delivered from October to February and is comprised of six compulsory taught modules. There are four optional modules to select the remaining two modules from.

Group project

The Group Project, which runs between February and April, enables you to put the skills and knowledge developed during the course modules into practice in an applied context while gaining transferable skills in project management, teamwork and independent research. The group project is usually 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. Potential future employers value this experience. This group project is shared across the MSc in Process Systems Engineering and other courses, 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. At the end of the project, all groups submit a written report and deliver a presentation to the industrial partner. This presentation provides the opportunity to develop interpersonal and presentation skills within a professional environment.

It is clear that the modern 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.

Part-time students are encouraged to participate in a group project as it provides a wealth of learning opportunities. However, an option of an individual dissertation is available if agreed with the Course Director.

Individual project

The individual research project allows you to delve deeper into a specific area of interest. As our academic research is so closely related to industry, it is very common for our industrial partners to put forward real-world problems or areas of development as potential research topics.

The individual research project component takes place between April/May and August for full-time students. For part-time students, it is common that their research projects are undertaken in collaboration with their place of work under academic supervision; given the approval of the Course Director.

Individual research projects undertaken may involve designs, computer simulations, feasibility assessments, reviews, practical evaluations and experimental investigations.

Typical research areas include:

  • Design, simulation and optimisation of process or energy systems.
  • Advanced process control methodologies.
  • Instrumentation and process measurement systems.
  • Multi-phase flow and processes.
  • Renewable energy systems.
  • Studies involving environmental issues.

Assessment

Taught modules 40%, Group project 20% (dissertation for part-time students), Individual Research Project 40%.

Your career

Graduates of the course have been successful in gaining employment in:

  • Engineering consultancies and design practices
  • Industry (oil and gas, petrochemical, chemical, food and drink, water and energy)
  • Research organisations
  • Central government departments
  • Local governments
  • Academic institutions.


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

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.

Example module listing

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.

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

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. The key learning outcomes include the abilities to:

  • 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

The programme primarily aims to develop skills for applying appropriate methods to analyse, develop, and assess process systems and technologies. The key learning outcomes include the abilities to:

  • 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

The programme aims to strengthen a range of transferable skills which are relevant to the needs of existing and future professionals in knowledge intensive industries irrespective of their sector of operation. The key learning outcomes include the further development of the skills in the following areas:

  • 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.



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

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.

Example module listing

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.

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.

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.

Learn more about opportunities that might be available for this particular programme by using our student exchanges search tool.



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This specialised stream enables you to develop an understanding of the mathematics relevant to systems engineering and gives an advanced treatment of control theory and modelling, along with their application to the field of process systems engineering. Read more

This specialised stream enables you to develop an understanding of the mathematics relevant to systems engineering and gives an advanced treatment of control theory and modelling, along with their application to the field of process systems engineering.

The Department of Chemical Engineering offers four courses that are built around a wide choice of advanced taught modules plus a research project in one of our research focus areas. The Advanced Chemical Engineering course allows students to undertake advanced study in chemical engineering coupled with appropriate background study in basic sciences, mathematics and computing techniques, while the specialised MSc streams give you the opportunity to explore one area of chemical engineering in more depth.

The Process Systems Engineering (PSE) course allows students to develop an understanding of the mathematics relevant to systems engineering and gives an advanced treatment of control theory, modelling, and design and management techniques, along with their application to the field of process systems engineering.

Further information

For full information on this course, including how to apply, see: http://www.imperial.ac.uk/study/pg/chemical-engineering/process-systems-engineering/ ;

If you have any enquiries you can contact our team at:



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This MSc is part of the Midlands Energy Graduate School (MEGS), a partnership between the universities of Nottingham, Birmingham and Loughborough. Read more
This MSc is part of the Midlands Energy Graduate School (MEGS), a partnership between the universities of Nottingham, Birmingham and Loughborough. Most modules taught by the universities of Nottingham and Loughborough are available either via state-of-the-art video-conferencing facilities, so students do not usually need to attend the other university in person. However, should any student wish to travel to partake directly in some lectures, advice can be provided on appropriate travel and accommodation.
Many of the core modules are delivered in one-week intensive blocks. Coupled with the major research project, the core modules will promote enquiry-based learning which will be supplemented by a range of optional technical and contextual/managerial modules.

Before you apply

You must be sure of the university within the MEGS consortium that you wish to study this MSc before you make an application. This will be dependent on the type of research project you are most interested in, you will apply to the university where you wish to undertake your research project.

We will help you asses which university is the most appropriate based on the above. Please contact the course director Dr Cheng-gong Sun, providing your degree subject and university and an outline of the fossil energy topics that interest you, we will then get back to you to advise where your application should be submitted.

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Engineers are the key to the development of society and solving the problems the world currently faces. They have the power to make the world fundamentally different. Read more
Engineers are the key to the development of society and solving the problems the world currently faces. They have the power to make the world fundamentally different.

The Master of Advanced Engineering is the key transitional stage in your career, transforming you into a global leader. Gain a depth of knowledge, mastering the crucial skills to become a leading contributor in your field.

Customise your degree - the Master of Advanced Engineering offers flexibility to complete your Master degree in just one year, or you can choose a two year option.

This course is designed to extend your knowledge in your chosen specialisation area and advance your leadership and complex problem-solving skills in a cross cultural environment.

Understand, reflect critically upon and apply methods in at least one specialist engineering area to design solutions to complex, multifaceted engineering problems.

Common core units will develop crucial skills in areas such as data analysis and entrepreneurship, translating theory into engineering practice. In discipline core units you will identify, interpret and critically appraise current developments and technologies within your specialisation.

Enhancement units are designed to provide breadth and are taken from either another engineering specialisation or in complementary areas such as information technology and business.

In addition, the two year version of the program offers a range of technical electives that will deepen your understanding of a specific topic, and two, year- long engineering project units. You will work closely with an academic on a topic of your choice and immerse yourself in a multidisciplinary design project.

The Master of Advanced Engineering could also be your stepping stone to a research degree. All of this in highly interactive, expert led classes.

Visit the website http://www.study.monash/courses/find-a-course/2016/advanced-engineering-e6001?domestic=true

Overview

Please select a specialisation for more details:

Chemical engineering

Your qualification will be a Master of Advanced Chemical Engineering

Please note that this specialisation is available only in Clayton.

The Master of Advanced Chemical Engineering allows you to engage in the areas of study including advanced reaction engineering, process design and optimization, conversion of bioresources into fuel, materials and specialty chemicals, and nanostructured membranes for sustainable separations and energy production with an emphasis on the latest developments in the field. In this course, you will develop specialised knowledge and skills that are important to Chemical Engineers in industry and research. This course provides graduates with enhanced opportunities for advancement in their careers.

Civil engineering (Infrastructure systems)

Your qualification will be a Master of Advanced Civil Engineering (Infrastructure Systems)

The Master of Advanced Civil Engineering (Infrastructure Systems) will equip graduates to work with in the area of infrastructure engineering and management. It will provide the fundamental knowledge associated with interfacing both structural and geotechnical designs for infrastructure systems. The program is designed to equip you with advanced skills necessary for managing the challenges posed by ageing and leading designs of new complex infrastructure systems. The course is suitable for new graduates, professionals and managers who are keen to upgrade their existing design and management skills, as well as to develop theoretical and applied knowledge in the area of infrastructure engineering and management.

Civil engineering (Transport)

Your qualification will be a Master of Advanced Civil Engineering (Transport)

Please note that this specialisation is available only in Clayton.

The Master of Advanced Civil Engineering (Transport) program deals with the fundamental knowledge associated with transport engineering and management, traffic engineering, intelligent transport systems and transport planning. The program in is a response to the growing need for engineers with broad awareness of the characteristics and significance of transport, including its technological, economic and social impact. At the same time, the program outlines the state-of-the-art of transport engineering, as it may be applied to the solution of real problems in the planning, design, management and operation of transport facilities. The course is suitable for new graduates, professionals and managers who are keen to upgrade their existing design and management skills as well as to develop theoretical and applied knowledge in the area of transport engineering and management.

Civil engineering (Water)

Your qualification will be a Master of Advanced Civil Engineering (Water)

Please note that this specialisation is available only in Clayton.

The Master of Advanced Civil Engineering (Water) allows you to major in water resources engineering and management. This program deals with the fundamental knowledge associated with surface and ground water flow, stormwater management, water quality, flood forecasting and mitigation. The program is designed to equip you with advanced skills necessary for managing the challenges posed by changing climatic condition on water resource management. The course is suitable for new graduates, professionals and managers who are keen to upgrade their existing design and management skills as well as to develop theoretical and applied knowledge in the area of water resources engineering and management.

Electrical engineering

Your qualification will be a Master of Advanced Electrical Engineering

Please note that this specialisation is available only in Clayton.

The Master of Advanced Electrical Engineering will give you a broad introduction to advanced techniques in signal processing, communications, digital systems and electronics. The units have been chosen around the common theme of embedded systems: special purpose computing systems designed for specific applications. They are found just about everywhere including in consumer electronics, transportation systems, medical equipment and sensor networks. The course will mix theory and practice and will contain a significant amount of hands-on learning in laboratories and team-based design projects.

Energy and sustainability engineering

Your qualification will be a Master of Advanced Engineering (Energy and Sustainability)

Please note that this specialisation is available only in Malaysia.

The Master of Advanced Engineering (Energy and Sustainability) is designed for qualified engineers keen to deepen their knowledge in the energy and sustainability area. The course provides foundations in general engineering through engineering analysis and entrepreneurship units. Students can major in this program by examining energy and sustainability area from a multi-disciplinary perspective. Students can also choose elective units such as environment and air pollution control and smart grids to further enhance their knowledge in this area or undertake a minor research work to pursue a topic of interest related to this area.

Materials engineering

Your qualification will be a Master of Advanced Materials Engineering

Please note that this specialisation is available only in Clayton.

The Master of Advanced Materials Engineering encompasses practical aspects of the key classes of materials such as metals, polymers, biomaterials, nanomaterials and energy-related materials. This program particularly focuses on the most up-to-date aspects of the field, along with the utilisation of materials and their electronic, chemical and mechanical properties as underpinned by the microstructures that are revealed by modern characterisation techniques. This program is designed to prepare students to appreciate and exploit the central role of materials in addressing the present technical, economic and environmental problems involved in the design and construction of engineering structures, processes and devices. This course is ideally suited for new graduates as well as professional engineers who are eager to advance their applied knowledge in the area of Materials Engineering.

Mechanical engineering

Your qualification will be a Master of Advanced Mechanical Engineering

Please note that this specialisation is available only in Clayton.

Most modern engineering projects are multidisciplinary in nature and require a broad range of skills, proficiencies and perspectives to accomplish the task. The Master of Advanced Mechanical Engineering takes a systems approach to the design, monitoring and performance of complex mechanical engineering systems in the fields of renewable energy, aerospace, buildings, transportation, and biomedical devices. The systems approach also permeates the design of the course: four discipline-based core units are vertically integrated so that common problems are examined from different perspectives, culminating in a sustainable systems unit.

For more information visit the faculty website - http://www.study.monash/media/links/faculty-websites/engineering

Find out how to apply here - http://www.study.monash/courses/find-a-course/2016/advanced-engineering-e6001?domestic=true#making-the-application

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

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.

Example module listing

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.

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

The programme aims to develop the knowledge and understanding in both petroleum refining and systems engineering. The key learning outcomes include:

  • 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.

The key learning outcomes include the abilities to:

  • 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

The programme primarily aims to develop skills for applying appropriate methods to the design and operation of petroleum refining processes. The key learning outcomes include the abilities to:

  • 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.

The key learning outcomes include the further development of the skills in the following areas:

  • 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 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. Read more

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.

Example module listing

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.

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

The programme aims to develop the knowledge and understanding in both process and environmental systems engineering. The key learning outcomes include:

  • 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

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.

The key learning outcomes include the abilities to:

  • 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

The programme primarily aims to develop skills for applying appropriate methods to analyse, develop, and assess process and environmental systems and technologies. The key learning outcomes include the abilities to:

  • 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

The programme aims to strengthen a range of transferable skills which are relevant to the needs of existing and future professionals in knowledge intensive industries irrespective of their sector of operation. The key learning outcomes include the further development of the skills in the following areas:

  • 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 specialised stream enables you to develop an understanding of the mathematics relevant to systems engineering and gives an advanced treatment of control theory and modelling, along with their application to the field of process systems engineering. Read more

This specialised stream enables you to develop an understanding of the mathematics relevant to systems engineering and gives an advanced treatment of control theory and modelling, along with their application to the field of process systems engineering.

The Department of Chemical Engineering offers four courses that are built around a wide choice of advanced taught modules plus a research project in one of our research focus areas.

The Advanced Chemical Engineering course allows students to undertake advanced study in chemical engineering coupled with appropriate background study in basic sciences, mathematics and computing techniques, while the specialised MSc streams give you the opportunity to explore one area of chemical engineering in more depth.

The Process Systems Engineering (PSE) course allows students to develop an understanding of the mathematics relevant to systems engineering and gives an advanced treatment of control theory, modelling, and design and management techniques, along with their application to the field of process systems engineering.

Further information

For full information on this course, including how to apply, see: http://www.imperial.ac.uk/study/pg/chemical-engineering/process-systems-engineering/

If you have any enquiries you can contact our team at:



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

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.

Example module listing

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.

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

The programme aims to develop the knowledge and understanding in both renewable energy and systems engineering. The key learning outcomes include:

  • 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

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. The key learning outcomes include the abilities to:

  • 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

The programme primarily aims to develop skills for applying appropriate methods to analyze, develop, and assess renewable technologies and systems. The key learning outcomes include the abilities to:

  • 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

The programme aims to strengthen a range of transferable skills which are relevant to the needs of existing and future professionals in knowledge intensive industries irrespective of their sector of operation. The key learning outcomes include the further development of the skills in the following areas:

  • 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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The Advanced Chemical Engineering with Information Technology and Management programme addresses recent developments in the global chemical industry by focusing on advancements of information technology and business management skills, including entrepreneurship. Read more
The Advanced Chemical Engineering with Information Technology and Management programme addresses recent developments in the global chemical industry by focusing on advancements of information technology and business management skills, including entrepreneurship.

It builds on the Department’s established strengths in computer modelling, process systems engineering, reaction engineering, numerical modelling, computational fluid dynamics, finite element modelling, process control and development of software for process technologies.

Teaching is augmented by staff from other departments and has an emphasis on design activities.

The programme aims to provide in-depth understanding of the IT skills required for advanced chemical processes and raise students’ awareness of the basic concepts of entrepreneurship, planning a new business, marketing, risk, and financial management and exit strategy.

Core study areas include process systems engineering and applied IT practice, research and communication, modelling and analysis of chemical engineering systems and a research project.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/chemical/advanced-chem-eng-it-management/

Programme modules

Core Modules
Semester 1:
- Process Systems Engineering and Applied IT Practice
- Research and Communication

Semester 2:
- Advanced Computational Methods for Modelling and Analysis of Chemical Engineering Systems

Semester 1 and 2:
- MSc Project

Optional Modules (select three)
Semester 1:
- Chemical Product Design
- Filtration
- Downstream Processing
- Colloid Engineering and Nano-science
- Hazard Identification and Risk Assessment

Semester 2:
- Mixing of Fluids and Particles

Optional Management Modules (select two)
Semester 1:
- Enterprise Technology

Semester 2:
- Entrepreneurship and Small Business Planning
- Strategic Management for Construction

Careers and further study

Our graduates go on to work with companies such as 3M, GE Water, GL Noble Denton, GSK, Kraft Food, Tata Steel Group, Petroplus, Shell, Pharmaceutical World and Unilever. Some students further their studies by enrolling on a PhD programme.

Why choose chemical engineering at Loughborough?

The Department of Chemical Engineering at Loughborough University is a highly active, research intensive community comprising 21 full time academic staff, in addition to research students, postdoctoral research fellows and visitors, drawn from all over the world.

Our research impacts on current industrial and societal needs spanning, for example, the commercial production of stem cells, disinfection of hospital wards, novel drug delivery methods, advanced water treatment and continuous manufacturing of pharmaceutical products.

- Facilities
The Department has excellent quality laboratories and services for both bench and pilot scale work, complemented by first-rate computational and IT resources, and supported by mechanical and electronic workshops.

- Research
The Department has a strong and growing research programme with world-class research activities and facilities. Given the multidisciplinary nature of our research we work closely with other University departments across the campus as well as other institutions. The Departments research is divided into six key areas of interdisciplinary research and sharing of expertise amongst groups within the Department is commonplace.

- Career Prospects
The Department has close working relationships with AstraZeneca, BP, British Sugar, Carlsberg, E.ON, Exxon, GlaxoSmithKline, PepsiCo and Unilever to name but a few of the global organisations we work with and employ our graduates.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/chemical/advanced-chem-eng-it-management/

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The Systems Engineering Management MSc has been specifically designed for the needs of engineering professionals working in the field of complex systems development. Read more

The Systems Engineering Management MSc has been specifically designed for the needs of engineering professionals working in the field of complex systems development. The programme encompasses not only the technical tools and approaches needed to build success in this area, but also the management dimension of the relevant processes.

About this degree

Students gain an integrated, interdisciplinary view of complex systems and an advanced understanding of the systems engineering process. They gain the ability to apply this process to a variety of real-world situations and the management skills necessary to facilitate the development of complex systems on time and within budget.

Students undertake modules to the value of 180 credits.

The programme consists of four core taught modules (60 credits) two optional taught modules (30 credits) and three research modules (90 credits). Modules are generally taught as intensive five-day 'block weeks' to minimise time away from the office.

A Postgraduate Diploma (120 credits, full-time one academic year, or flexible study up to five years) is offered.

A Postgraduate Certificate (60 credits, full-time 12 weeks, or flexible study up to three years) is offered.

Core modules

  • Systems Thinking and Engineering Management
  • The Business Environment
  • Risk, Reliability, Resilience
  • Lifecycle Management

Optional modules

Students choose two of the following:

  • Systems Design
  • Technology Strategy
  • Project Management (leading to Association for Project Management exam)
  • Delivering Complex Projects
  • Defence and Security Systems
  • Rail Systems
  • Space Systems

Research modules

All MSc students undertake a structured research programme comprising the following mandatory modules:

  • Systems Engineering in Practice (15 credits)
  • Systems Engineering Project Concept (15 credits)
  • Systems Engineering Research Project (60 credits)

Teaching and learning

The programme is delivered through a combination of lectures, discussion sessions, workshop activity, and project work. Each taught course will be separately assessed through a combination of course work and a written examination. The project will be assessed through written dissertation and subsequent oral examination.

Further information on modules and degree structure is available on the department website: Systems Engineering Management MSc

Careers

Complex systems are commonplace in many branches of UK industry including rail, aerospace, defence, and manufacturing. The ability to create such systems effectively is crucial to the competitiveness of these industries and has a direct bearing on the wealth of the nation.

Recent career destinations for this degree

  • Engineering Manager, BAE Systems
  • Systems Engineer, BIG
  • Analyst, Accenture
  • Proposals engineer, Invensys PLC

Why study this degree at UCL?

This MSc combines academic rigour with the practical expertise exemplified by our collaborators in UK industry and government. The flexible programme enables participants to structure their studies to suit their own career goals, and is accredited by the Institution of Engineering and Technology (IET) as a programme of further learning for registration as a Chartered Engineer.

The programme combines interactive lectures, group exercises and case studies to reinforce key points. Lecturers are experts in the field, many of whom have engaged in the practice of systems engineering in industry, and all of whom oversee research across a broad range of subjects relating to systems engineering, project management and technology management.

Industry is operating in an environment where technology changes rapidly, and where global competition grows ever more intensive. The challenge to remain competitive means we must make the right thing at the right price. Our MSc equips graduates with the skills to meet this challenge.



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The global shortage of qualified civil engineers includes specialists in water engineering and this MSc programme helps redress this imbalance by providing graduates with an advanced knowledge and skill base to equip them for senior industry roles. Read more

About the course

The global shortage of qualified civil engineers includes specialists in water engineering and this MSc programme helps redress this imbalance by providing graduates with an advanced knowledge and skill base to equip them for senior industry roles.

Brunel’s MSc in Water Engineering is unique in providing specialist knowledge on the critical sub-topics of water and wastewater management and engineering, desalination systems, building water services engineering, industrial waste water management, and water in health care.

The programme demonstrates the links between theory and practice by including input from our industrial partners and through site visits. This is a key aspect for establishing a competitive and high added value course that provides adequate links with industry.

Features of the course include:

Students’ skills in gathering and understanding complex information from a variety of sources (including engineering, scientific and socio-economic information) will be developed in an advanced research methods module. 

Issues relating to risk and health and safety will be introduced in the research methods module and built on in specialist modules. 

Generic modules in financial and project management will underpin specialist modules focusing on water engineering topics.

Real problem-solving examples – starting from basic principles, to the identified problem, the solution, the implementation process and was implemented and the end result. 

Real case studies – demonstrating how environmental and economic sustainability is considered within civil engineering, particularly in water resources management.

Aims

Problems associated with water resources, access, distribution and quality are amongst the most important global issues in this century. Water quality and scarcity issues are being exacerbated by rising populations, economic growth and climate change*.

Brunel's programme in Water Engineering aims to develop world class and leading edge experts on water sustainability who are able to tackle the industry’s complex challenges at a senior level. During the programme you will also learn about the development and application of models that estimate the carbon and water footprint within the energy and food sector.

The MSc is delivered by experienced industry professionals who bring significant practical experience to the course – and the University’s complete suite of engineering facilities and world-class research experience are set up for development and engineering of advanced systems, testing a variety of processes, designs and software tools.

*Recent figures indicate that 1.1 billion people worldwide do not have access to clean drinking water, while 2.6 billion do not have adequate sanitation (source: WHO/UNICEF 2005). 

Course Content

The primary aim of this programme is to create master’s degree graduates with qualities and transferable skills for demanding employment in the water engineering sector. Graduates will have the independent learning ability required for continuing professional development and acquiring new skills at the highest level.

Specific aims are as follows:

- To provide education at postgraduate level in civil engineering. 
- To develop the versatility and depth to deal with new, complex and unusual challenges across a range of water engineering issues, drawing on an understanding of all aspects of water engineering principles. 
- To develop imagination, initiative and creativity to enable graduates to follow a successful engineering career with national and international companies and organisations. 
- To provide a pathway that will prepare graduates for successful careers including, where appropriate, progression to Chartered Engineer status.

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

Knowledge and understanding of:

- The principles of water engineering, including fluid mechanics, hydrology, and sustainable design. 
- Specialist areas that impact on the successful application of water engineering knowledge projects, e.g. sustainable construction management, financial management and risk analysis. 
- The interplay between engineering and sustainability in complex, real-world situations.

At the cognitive level students will be able to:

- Select, use and evaluate appropriate investigative techniques.
- Assemble and critically analyse relevant primary and secondary data.
- Recognise and assess the problems and critically evaluate solutions to challenges in managing water engineering projects.
- Evaluate the environmental and financial sustainability of current and potential civil engineering activities.

Personal and transferable skills that students develop will allow them to:

- Define and organise a substantial advanced investigation. 
- Select and employ appropriate advanced research methods. 
- Organise technical information into a concise, coherent document.
- Effectively employ a variety of communication styles aimed at different audiences. 
- Plan, manage, evaluate and orally-presented personal projects. 
- Work as part of, and lead, a team.

Typical Modules

Each taught module will count for 15 credits, approximating to 150 learning hours. The Master's programme can be taken full time, over 12 months. The first eight months of the full time course will eight taught modules. For the final four months, students will complete a dissertation counting for 60 credits. Modules cover:

Sustainable Project Management
GIS and Data Analysis
Water Infrastructure Engineering
Risk and Financial Management
Hydrology & Hydraulics
Water Treatment Engineering
Water Process Engineering
Research Methods
Civil Engineering Dissertation

Teaching

Our philosophy is to underpin theoretical aspects of the subject with hands-on experience in applying water engineering techniques. Although you may move on to project management and supervision roles, we feel it important that your knowledge is firmly based on an understanding of how things are done. To this end, industrial partners will provide guest lectures on specialist topics.

In addition to teaching, water engineering staff at Brunel are active researchers. This keeps us at the cutting edge of developments and, we hope, allows us to pass on our enthusiasm for the subject.

How many hours of study are involved?

Contact between students and academic staff is relatively high at around 20 hours per week to assist you in adjusting to university life. As the course progresses the number of contact hours is steadily reduced as you undertake more project-based work.

How will I be taught?

Lectures:
These provide a broad overview of the main concepts and ideas you need to understand and give you a framework on which to expand your knowledge by private study.
Laboratories:
Practicals are generally two- or three-hour sessions in which you can practise your observational and analytical skills, and develop a deeper understanding of theoretical concepts.
Design Studios:
In a studio you will work on individual and group projects with guidance from members of staff. You may be required to produce a design or develop a solution to an engineering problem. These sessions allow you to develop your intellectual ability and practice your teamwork skills.
Site visits:
Learning from real-world examples in an important part of the course. You will visit sites featuring a range of water engineering approaches and asked to evaluate what you see.
One-to-one:
On registration for the course you will be allocated a personal tutor who will be available to provide academic and pastoral support during your time at university. You will get one-to-one supervision on all project work.

Assessment

Several methods of assessment are employed on the course. There are written examinations and coursework. You will undertake projects, assignments, essays, laboratory work and short tests.

Project work is commonplace and is usually completed in groups to imitate the everyday experience in an engineering firm, where specialists must pool their talents to design a solution to a problem.

In this situation you can develop your management and leadership skills and ensure that all members of the group deliver their best. Group members share the mark gained, so it is up to each individual to get the most out of everyone else.

Special Features

Extensive facilities
Students can make the most of laboratory facilities which are extensive, modern and well equipped. We have recently made a major investment in our Joseph Bazalgette Laboratories which includes hydraulic testing laboratory equipment and facilities such as our open channel flow flumes.

Personal tutors
Although we recruit a large number of highly qualified students to our undergraduate, postgraduate and research degrees each year, we don’t forget that you are an individual. From the beginning of your time here, you are allocated a personal tutor who will guide you through academic and pastoral issues.

World-class research
The College is 'research intensive' – most of our academics are actively involved in cutting-edge research. Much of this research is undertaken with collaborators outside the University, including construction companies, water utilities, and other leading industrial firms. We work with universities in China, Poland, Egypt, Turkey, Italy, Denmark and Japan. This research is fed directly into our courses, providing a challenging investigative culture and ensuring that you are exposed to up-to-date and relevant material throughout your time at Brunel.

Strong industry links
We have excellent links with business and industry in the UK and overseas. This means:
Your degree is designed to meet the needs of industry and the marketplace.
The latest developments in the commercial world feed into your course.
You have greater choice and quality of professional placements.
We have more contacts to help you find a job when you graduate.

Visting Professors 
The Royal Academy of Engineering - UK’s national academy for engineering has appointed senior industrial engineers as visiting professors at Brunel University London.
The Visting Professors Scheme provides financial support for experienced industrial engineers to deliver face-to-face teaching and mentoring at a host of institutions. Our engineering undergraduates will benefit from an enhanced understanding of the role of engineering and the way it is practised, along with its challenges and demands. 

Women in Engineering and Computing Programme

Brunel’s Women in Engineering and Computing mentoring scheme provides our female students with invaluable help and support from their industry mentors.

Accreditation

This course has been designed in close consultation with the industry and is accredited as a designated 'technical' MSc degree by the Join Board of Moderators (JBM). The JBM is made up of Institution of Highways and Transport and the Institution of Highway Engineeres respectively.

1. This means this course provides Further Learning for a Chartered Engineer who holds a CEng accredited first degree (full JBM listing of accredited degrees).
2. As a designated ‘technical’ MSc, it will also allow suitable holders of an IEng accredited first degree to meet the educational base for a Chartered Engineer.

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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.

Coursework and assessment

Assessment is a combination of examinations and submitted coursework.

Examinations take place in the January and May of each year at the University of Manchester. Distance learning students who do not live in mainland UK can take examinations at a local British Council office or University. You would be expected to meet the cost of the supervision of each exam if taken away from Manchester.

The Dissertation Project forms a major part of the MSc course and provides useful practice in carrying out academic research and writing in an area that you are interested in. You learn to apply your knowledge by solving industry-based problems and demonstrate the knowledge you have acquired by solving an original problem. You choose a topic from a wide selection provided by the University's teaching staff and by industry.  Students have the opportunity of working with large engineering or engineering software development companies and The Process Integration Research Consortium (comprising approximately 30 international companies) also provides opportunities for students to discuss project work in a large number of engineering related areas.

Course unit details

A full list of course units is avaialble here

Disability support

Practical support and advice for current students and applicants is available from the Disability Advisory and Support Service. Email: 

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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IN THIS INTENSIVE, PART-TIME, 18-MONTH ONLINE PROGRAM YOU WILL GAIN. - Skills and know-how in the latest technologies in electrical engineering. Read more

IN THIS INTENSIVE, PART-TIME, 18-MONTH ONLINE PROGRAM YOU WILL GAIN:

- Skills and know-how in the latest technologies in electrical engineering

- Practical guidance from electrical engineering experts in the field

- Knowledge from the extensive experience of the lecturers, rather than from only the theoretical information gained from books and college

- Credibility as the local electrical engineering expert in your firm

- Networking contacts in the industry

- Improved career prospects and income

- An Advanced Diploma of Applied Electrical Engineering (Electrical Systems)

Next intake starts July 02, 2018. Registrations are now open.

Payment is not required until 2 to 4 weeks before the start of the program.

The EIT Advanced Diploma of Applied Electrical Engineering (Electrical Systems) is recognized worldwide and has been endorsed by the International Society of Automation (ISA). Please ask us about specific information on accreditation for your location.

OVERVIEW

Join the next generation of electrical engineers and technicians and embrace a well paid, intensive yet enjoyable career by embarking on this comprehensive course on electrical engineering. It is presented in a practical and useful manner - all theory covered is tied to a practical outcome. Leading electrical engineers who are highly experienced engineers from industry, having 'worked in the trenches' in the various electrical engineering areas present the course over the web in a distance learning format using our acclaimed live e-learning techniques.

The course starts with an overview of the basic principles of electrical engineering and then goes on to discuss the essential topics in depth. With a total of 16 modules, everything that is of practical value from electrical distribution concepts to the equipment used, safety at work to power quality are all looked at in detail. Each module contains practical content so that the students can practice what they learn including the basic elements of designing a system and troubleshooting.

Most academic courses deal with engineering theory in detail but fall short when it comes to giving practical hints on what a technician is expected to know for a job in the field. In this course, the practical aspects receive emphasis so that when you go out into the field you will have the feeling that ‘you have seen it all.

*JOB OUTCOMES, INTERNATIONAL RECOGNITION AND PROFESSIONAL MEMBERSHIP:

A range of global opportunities awaits graduates of the Advanced Diploma of Applied Electrical Engineering (Electrical Systems). Pending full accreditation you may become a full member of Engineers Australia and your qualification will be recognized by Engineers Australia and (through the Dublin Accord) by leading professional associations and societies in Australia, Canada, Ireland, Korea, New Zealand, South Africa, United Kingdom and the United States. The Dublin Accord is an agreement for the international recognition of Engineering Technician qualifications.

For example, current enrolled students can apply for free student membership of Engineers Australia. After graduation, you can apply for membership to become an Engineering Associate, while graduates interested in UK recognition can apply for membership of the Institution of Engineering and Technology (IET) as a Technician Member of the Institution of Engineering and Technology.

This professional recognition greatly improves the global mobility of graduates, and offers you the opportunity of a truly international career.

You will be qualified to find employment as an Engineering Associate in public and private industry including transportation, manufacturing, process, construction, resource, energy and utilities industries. Engineering Associates often work in support of professional engineers or engineering technologists in a team environment. If you prefer to work in the field you may choose to find employment as a site supervisor, senior technician, engineering assistant, or similar.

WHO SHOULD COMPLETE THIS PROGRAM?

- Electrical Engineers and Technicians

- Project Engineers

- Design Engineers

- Instrumentation and Design Engineers

- Electrical Technicians

- Field Technicians

- Electricians

- Plant Operators

- Maintenance Engineers and Supervisors

- Energy Management Consultants

- Automation and Process Engineers

- Design Engineers

- Project Managers

- Instrument Fitters and Instrumentation Engineers

- Consulting Engineers

- Production Managers

- Chemical and Mechanical Engineers

- Instrument and Process Control Technicians

In fact, anyone who wants to gain solid knowledge of the key elements of electrical engineering – to improve work skills and to create further job prospects. Even those of you who are highly experienced in electrical engineering may find it useful to attend some of the topics to gain key, up to date perspectives on electrical engineering.

PROGRAM STRUCTURE

The course is composed of 16 modules. These cover the following seven main threads to provide you with maximum practical coverage in the field of electrical engineering

- Electrical technology fundamentals

- Distribution equipment and protection

- Rotating machinery and transformers

- Power electronics

- Energy efficiency

- Earthing and safety regulations

- Operation and maintenance of electrical equipment

The 16 modules will be completed in the following order:

- Electrical Circuits

- Basic Electrical Engineering

- Fundamentals of Professional Engineering

- Electrical Drawings

- Electrical Power Distribution

- Transformers, Circuit Breakers and Switchgear

- Electrical Machines

- Power Cables and Accessories

- Earthing and Lightning / Surge Protection

- Power System Protection

- Electrical Safety and Wiring Regulations

- Testing, Troubleshooting and Maintenance of Electrical Equipment

- Energy Efficiency and Energy Use

- Power Quality

- Power Electronics and Variable Speed Drives

- DC and AC High Reliability Power Supplies

COURSE FEES

What are the fees for my country?

The Engineering Institute of Technology (EIT) provides distance education to students located all around 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. We aim to give you a rapid response regarding course fees that are relevant to your individual circumstances.

We understand that cost is a major consideration before a student begins to study. For a rapid reply to your query regarding course fees and payment options, please contact a Course Advisor in your region via the below button and we will respond within two (2) business days.



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