Last Updated on August 28, 2023
If you are interested in reading more about the details of a UK Engineering doctorate programme, then this blog is for you. Far from simply providing a listing of facts, we take you through the entire application process, detailing all the things you need to consider throughout your course of study. Our aim is to provide impartial advice and information that will help to shape your decision – making your journey to qualification as seamless as possible.
Right here on College learners, you are privy to a litany of relevant information on doctor of engineering salary, engd chemical engineering, engineering doctorate programs uk, and so much more. Take out time to visit our catalog for more information on similar topics.
Engineering Doctorate Uk
About the programme
The EngD is designed to integrate easily with your work and host organisation. It aims to:
- provide a rigorous Doctorate level environment within which important current and future engineering issues are investigated;
- develop your critical thinking skills and awareness of the application of technology into organisations
- develop your research and management skills, such as leadership and change management, necessary to deal with the complex issues in today’s and future engineering business activities
- enable the effective management of innovation
- provide a supervisory environment that helps give guidance, review and advice on the development of your portfolio, specialist technological skills and the research process
Study on the EngD will require periodic attendance at the University. There is no requirement to study any taught modules on this Professional Doctorate research degree. However, as part of the EngD, students are required to undertake a programme of professional development which may include attendance at conferences and other professional meetings or training in specific methods and technologies. The key unique feature of the EngD is that it is based on a portfolio of research work. This more flexible approach replaces the traditional ‘single topic’ focus of a PhD. Your portfolio will centre on a key theme and investigate areas such as technical, business and process concepts. These projects should be linked closely with your day to day work for maximum benefit to both you and your company.
Why choose this programme?
- This Engineering Doctorate programme aims to develop future technological leaders;
- You undertake your studies on a key theme relating to your profession or professional practice;
- Your project offers the opportunity to investigate different facts of a problem relating to your profession;
- You may start the EngD in either September or January.
The EngD aims to develop future technological leaders and technical managers through improved specialist skills applied in an organisational setting. The EngD has been designed to help develop industry-based technical specialists for whom a PhD would be a natural next step, but who are looking for greater flexibility and enterprise-focus. In particular the EngD is based on a portfolio of research work, which enables students to study at doctorate level but move away from the traditional ‘single topic’ focus of a PhD to centre the contribution to knowledge around the organisation. The portfolio focuses on a key theme and then investigates different facets such as technical engineering improvements and enhanced business practices and processes. These projects are typically linked closely to the student’s day-to-day work for maximum benefit.
A first degree in engineering or science. Applicants with a Master’s degree may move more rapidly into their research phase. A minimum IELTS score of 6.0. TOEFL 550 (213 CBT) or equivalent is required for those for whom English is not their first language.
doctor of engineering salary
The national average salary for a Phd Engineer is $104,263 in United States.
engd chemical engineering
University of Birmingham: School of Chemical Engineering
Within the Unilever Beauty and Personal Care (BPC) portfolio, products with a wide range of rheological and physical properties can be found which can be defined by their specific microstructure which includes complex fluids and solid product formats. Much research is actively being conducted of processing of complex fluids, yet comparatively limited research is dedicated to the field of solid product formats.
The proposed research project aims to gain a better understanding of the processing challenges for this format, in particular powder and granulated systems. The manufacture of BPC products is achieved through the sequential addition of raw materials in a defined order, specified rates of addition and controlled temperature profiles.
Thus, there are two attributes which vary throughout the manufacturing process of BPC products:
(1) increasing mass within the batch vessel and
(2) variations in rheological and physical properties for each of the intermediate stages, affected by the composition and processing conditions.
These two attributes will impact the achievable mixing intensity and efficiency, as well as mix characteristics within the vessel. This, in turn, affects product quality in terms of both physical properties (e.g., particle size, flowability, etc) and performance (i.e., dissolution), energy requirements and overall process optimisation.
The proposed research project aims to explore these three effects for the processing of high surfactant content powders (impact of manufacturing conditions, variations in physical properties of resultant product, and product performance). This can be achieved through use of dynamic torque measurements and flow characterisation techniques, such as positron emission particle tracking (PEPT), and a range of powder characterisation techniques. In addition, the project will explore the numerical simulation space to identify an approach that would allow tracking the evolution of the vessel level and product rheology throughout the process, using experimental results for validation.
University College London: Department of Biochemical Engineering
Biological products and their manufacture are progressing to unparalleled levels of complexity. Examples include engineered biocatalysts, antibody-drug conjugates, multivalent vaccines and cellular therapies. Each poses new and unique challenges to ensure they are produced in a safe, sustainable and cost-effective manner. The Centre for Doctoral Training is designed to develop the bioprocess engineering leaders of the future who will underpin the translation of new scientific advances into safe, selective and manufacturable therapies for what are often currently intractable conditions, but at affordable costs. To achieve this we embed our Engineering Doctorates (EngDs) within the vibrant research community at UCL and with internationally leading industry collaborators.
Students admitted to the CDT will complete a four-year EngD in collaboration with a company partner.
EngD programs provide engineers and scientists with full research training at the life sciences interface that is relevant to bioprocessing and related technologies. Each equips students with the requisite knowledge and terminology in current life science subjects to allow them to explore topics in their own research project under direction from their supervisory team.
Students come from a wide range of disciplines including Life Sciences, Engineering, and Physical Sciences , with interests in bioprocess research at the interfaces of biochemistry, chemical and biochemical engineering, mechanical engineering, chemistry, physics, and computational sciences. Research topics span bioprocess design, mammalian cell culture, cell and gene therapy, stem cell processing, protein engineering, bioanalytics, formulation, process automation, microfluidics, process and cost modelling, biocatalysis and synthetic biology. The doctoral research is complemented by taught courses and case studies designed to familiarise the student with bioprocessing topics, the life sciences interface and also the business and regulatory environment.
Students in our internationally renowned Department make use of the recent £30m of investment in comprehensive and unique facilities including a fully equipped pilot-plant, a micro-engineering facility with robotics systems and advanced regenerative medicine labs. All of these are underpinned by state of the art analytical equipment.
University of Nottingham: EPSRC CDT in Resilient Decarbonised Fuel Energy Systems
About the Project
This project will explore the fundamental link between biomass milling, classification and conveying to optimise biomass processing. The project will explore the fundamental science of milling fracture mechanics to develop a test for the critical particle size for comminution through compression for biomass particles. This test will be bench marked against the industry standard bond work index milling test and milling in a lab scale vertical spindle mill.
The fundamental science behind classification will be investigated to ascertain the impact of biomass particle size and shape on classification and linked back to milling fracture mechanics. A model will be developed which can predict if classification will be successful based on the milled product from the grinding bed. An existing rig which examines biomass conveying in pipes will be further developed to analyse a wide range of biomass particle flow conditions.
A novel biomass particle roping rig will be built to investigate roping and its link to biomass particle size and shape. Roping mitigation strategies will be developed, which will then be verified on a laboratory vertical spindle mill with pneumatic classification.
This would be a four-year project based in the new Resilient Decarbonised Fuel Energy Systems CDT based at The University of Nottingham and working alongside Net Zero Research partners.
We are seeking applicants to start in October 2022. Applicants are expected to have obtained (or be heading for) a First or Upper-second degree at Master’s level (or equivalent) in Mechanical or Chemical Engineering and be highly motivated. The project will be a mixture of lab based and modelling experiments. They should have broad interests in renewable and low carbon technologies, and in the application of these technologies. Furthermore, the applicant should have a desire to gain industrial experience during the EngD. Applicants should also be able to demonstrate excellent written and oral communication skills, which will be essential for collaborations, disseminating the results via journal publications and attendance at international conferences.
The PhD student will work within the EPSRC Centre for Doctoral Training (CDT) “Resilient Decarbonised Fuel Energy Systems”. In addition to the standard EPSRC stipend and payment of UK fees, there will be a stipend enhancement of £3,750 per annum for 4 years, with £6,000 per annum of funding for research costs and travel.