Explore our Advanced Mechanical Engineering taught Master's degree.

P-H341

MSc

1 year full-time

2 October 2023

Engineering

University of Warwick

The Advanced Mechanical Engineering MSc focuses on key skills required for a career in mechanical engineering. Warwick's School of Engineering, ranked 6th in the UK (Guardian University Guide 2022 for General Engineering), will provide you with versatility and depth of knowledge.

This course is accredited by the IET, and IMechE and InstMC. More information is available on the School of Engineering websiteLink opens in a new window.

Our Advanced Mechanical Engineering MSc focuses on the key skills required by the modern mechanical engineer.

You will develop the versatility and depth of knowledge to deal with new and unusual challenges across a wide range of disciplines, within engineering and beyond. Teaching is underpinned by research in automotive systems, biomedical engineering, solid and fluid mechanics, electrical and thermal energy systems, energy conversion/storage and sustainable cities.

You will also complete an individual research project – an in-depth experimental, theoretical or computational investigation of a topic chosen by you in conjunction with your academic supervisor.

The degree comprises eight taught modules and a project. The individual research project is an in-depth experimental, theoretical or computational investigation of a topic chosen by you in conjunction with your academic supervisor.

Previous project titles include: CFD for electric car battery cooling system design; Developing and testing an improved solar thermal collector (for hot water); Modelling and simulation of biological control systems; Recycling of materials from spent lithium ion batteries; Biomechanical detection of breast cancer by palpation; Polymer gear contact simulations for EV gearbox applications.

Class sizes for lectures, practical laboratory sessions and seminars vary depending on the number of students taking the module.

The MSc degree (totalling 180 credits) comprises:

• Eight taught modules (15 credits each)
• A research project (60 credits)

The typical workload for a 15-credit module is as follows:

• 20-30 hours of lectures/seminars
• 5 hours of laboratory work
• 45 hours of private/directed study
• 70 hours of assessed work

The research project is valued at 60 credits and students should plan to execute around 600 hours of work towards the completion of the project dissertation.

A combination of coursework and written examinations.

Reading lists

Most departments have reading lists available through Warwick Library. If you would like to view reading lists for the current cohort of students you can visit our Warwick Library web page.

Your timetable

Your personalised timetable will be complete when you are registered for all modules, compulsory and optional, and you have been allocated to your lectures, seminars and other small group classes. Your compulsory modules will be registered for you and you will be able to choose your optional modules when you join us.

A minimum 2:i undergraduate UK Honours degree or equivalent international qualification, in an engineering, physical sciences or mathematical subject.

You can see how your current degree score or GPA equates to the British system in our Study pages in the equivalent scores table.

We are willing to consider applications from students with lower qualifications on a case-by-case basis, particularly when the applicant can evidence relevant employment, practical experience or strong performance in undergraduate modules related to their proposed postgraduate course of study.

To ensure you have the essential foundations for the course, and depending on your overall academic profile, we may require you to take a mathematical skills test.

• Band A
• IELTS overall score of 6.5, minimum component scores not below 6.0.

There are no additional requirements for this course.

Additional Course Costs

This course may also include additional costs.

Additional Course Costs

This course may also include additional costs.

Individual Project

This module gives you the opportunity to demonstrate that you have independently contributed primary data and/or a new analysis of secondary data, within your chosen advanced research topic.

Projects will be highly variable in nature to reflect the range of topics within the programmes of study but all will provide you with an opportunity to achieve the learning outcomes. Thus, projects may entail experimentation, modelling, analysis and literary survey skills to develop advanced skills in the discovery and occasionally creation of new knowledge. The module also offers the chance for you to pursue curiosity driven work guided by an academic supervisor.

Mechanical Engineering Group Design

The design projects aim to give you the experience of working within a team, and parallels the way engineers often work in industry. You will integrate your knowledge and understanding in order to specify and solve a substantial Mechanical Engineering problem (or user need), through the creation and development of a product, process or system. The project also allows you to develop your understanding of project management, time management, ethics, sustainability, health and safety, risk, regulatory requirements, and intellectual property rights. You will also develop effective communication and leadership skills.

Research Methods and Professional Skills

The module aims to equip you with the research skills necessary to support masters’ level learning in engineering and facilitate engagement with the individual project through equipping you with a broad research skill set. In addition, this module will provide you with the professional and team skills to support the course and your career in engineering.

Computational Fluid Dynamics

The aim of this module is to provide a fundamental understanding of important numerical techniques in computational fluid dynamics and to establish a critical view on the use of CFD as part of the design process. This module offers an increased depth and range of specialist knowledge in computational fluid dynamics required by IMechE.

Precision Engineering and Microsystems

This module aims to provide a rigorous understanding of first-principles mechanical design applied at the limits of practical performance. You will be introduced to ideas and methodologies suited to precise dimensional and positional control and to miniaturization that are essential to modern technology, e.g. in the large UK instrumentation sector, as sub-systems for use in aerospace, automotive, etc. Additionally, this module provides insights into the science and practice of metrology.

Dynamic Analysis of Mechanical Systems

This module aims to deliver an overview of important techniques of engineering dynamics, and providing insight into advanced knowledge in kinematics, kinetics, and vibrations. The dynamics of engineering systems important to modern engineering applications such as spatial mechanisms and robots are examined. The complexities of kinematic and kinetic analysis of fully 3D motion will provide an appropriate challenge for the Master's level course.

Heat Transfer Theory and Design

Heat Transfer Theory and Design provides a knowledge of heat transfer that is of vital importance in many industrial sectors from process industries, through vehicles, etc., power plant, to building technology.

• Fundamental Fluid Mechanics for Mechanical Engineers
• Finite Elements Methods
• Renewable Energy
• Biomechanics

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