MSc Thermal Power & Fluid Engineering / Course details

This pioneering course has been taught here at the University for almost 40 years. Today, we continue to provide the training and education needed for thermofluid engineers to adapt and prepare for the everchanging demands of the modern world.

Whether you're a recent engineering or science graduate, someone looking to transition from closely related disciplines like Mechanics, Mathematics, or Physics, or a professional looking to not only enhance their expertise in thermofluids but develop skills in analytical, computational, and experimental methods, this course is carefully designed to nurture your potential. The advanced methods taught on this course for the analysis of heat and fluid flow are sought-after in both industrial and research applications.

The objectives of this course are to produce postgraduate specialists with:

• An advanced understanding of heat and fluid flow processes and their role in modern methods of power generation
• An in-depth understanding of numerical and experimental techniques in heat and fluid flow

Teaching on the course is delivered by academics from our world-leading research group in the field of turbulence modelling and heat transfer.

This is a full-time course studied over 12 months with one start date each year in September. Every year this MSc course in Thermal Power and Fluid Engineering attracts a large number of applications from all around the world, which allows us to select only the best candidates.

Throughout the course, alongside the teaching, special emphasis is placed on both computational and experimental work; the aim is to provide insight through experimentally observed phenomena, and also to provide practical/computational experience of a wide range of measurement and data analysis techniques. Thus, the course has a strong practical orientation which is supported by our department laboratories and facilities and it aims to produce engineers who are able to engage in the design, development and testing of internal combustion engines, turbines or power producing devices. Whilst on the course, students have the opportunity to participate in a number of industrial visits. Relevant companies sometimes offer projects to our students as a result of these visits.

The MSc is continually reviewed and now includes course units such as research and experimental methods, advanced fluid mechanics, advanced heat transfer, engineering thermodynamics, power engineering and computational fluid dynamics. Students are assessed based upon a combination of coursework, laboratory calculations, exams and projects. Upon successful completion of taught modules the students are required to do a research dissertation.