Aerospace Engineering MEng

Compulsory

• Engineering Mathematics and Programming I

  Aims: To develop students’ ability to understand and apply fundamental methods of engineering mathematics; to introduce the use of programming in engineering, and develop students’ ability to represent and solve problems algorithmically.

• Engineering Mathematics and Programming II

  Aims:  To develop students’ ability to understand and apply fundamental methods of engineering  tmathematics;o introduce the use of programming in engineering, and develop students’ ability to represent and solve problems algorithmically.

• Engineering Practice

  Aims: To develop the skills required by students studying in all engineering disciplines, thereby supporting their journey through Higher Education and into their professional life with the intention of maximising their employability. Skills development in the following areas will be addressed: problem solving; personal development; professional development; career planning; basic engineering design; introductory project management; communication; working in inclusive teams; health and safety; security.

• Engineering Systems and Energy 1

  Aims: To provide a grounding in concepts of measurement and uncertainty; to provide knowledge about applied physics relations that govern engineering systems within their boundaries and via their variables of interaction; to establish ability to define system boundaries and apply relevant simple models.

• Engineering Systems and Energy 2

  Aims: To provide a grounding in concepts of measurement and uncertainty; to provide knowledge about applied physics relations that govern engineering systems within their boundaries and via their variables of interaction; to establish ability to define system boundaries and apply relevant simple models.

• Engineering Mechanics - Statics

  Aims: To provide a grounding in the fundamental principles of engineering mechanics; to provide knowledge and understanding of Newton’s laws and their application for the solution of static problems; to provide experience and confidence in problem-solving.

• Engineering Mechanics and Materials (Mechanical and Aerospace)

  Aims: To provide a grounding in the fundamental principles of engineering mechanics – dynamics of rigid bodies; to provide knowledge and understanding of the common and important material properties for various engineering applications; to provide experience and confidence in problem-solving.

• Mechanical Engineering Science

  Aims: To present principles governing the mechanics of solid bodies under static condition; to present interpret and apply concepts and theories of classical engineering thermodynamics, fluid mechanics and heat transfer to engineering systems; to develop knowledge, understanding and skills in modelling and analysing engineering problems; to achieve an appreciation of laboratory instrumentation and data analysis.

Compulsory

• Engineering Mathematics and Programming

  The aim of this module is to enhance knowledge about application of mathematical modelling to engineering problems and to provide knowledge and understanding about various mathematical techniques that are used to solve mathematical problems relevant to engineering. Programming techniques will also be introduced for solving mathematical models

• Design Process for Machine Elements, Manufacturing Processes, Materials and CAD
  This module introduces relevant mechanical components, assemblies in an engineering design context and Computer Aided Design (CAD). Students learn to consolidate the disciplines of materials science, materials engineering and modern manufacturing processes.
• Engineering Business (Core)
  This module helps to develop and demonstrate an understanding of project management by working as part of a team to research and plan a project and enhances student preparedness for work placement and employment.
• Aerodynamics and CFD
  This module provides introduction to the fundamental principles of aerodynamics and development of experimental laboratorial procedures for basic aerodynamics. Students learn basic concepts of Computational Fluid Dynamics (CFD) to be used in aerodynamics problems.
• Solid Mechanics and Intro to FEA
  This module helps to establish a solid foundation for the analysis of solids and structures based on the fundamental principles of continuum mechanics. Students learn to link models and engineering applications with a range of real-life examples, experimental testing and comparative analysis of experimental measurements and theoretical results.
• Flight Mechanics and Aircraft Design
  This module introduces the basic principles of aircraft flight performance, stability and control, and aircraft design.
• Thermodynamics and Heat Transfer
  This module introduces new fundamental concepts of thermodynamics and apply to relevant thermal power and heating/cooling systems. Students learn basic concepts of heat transfer.
• Dynamics of Machines
  This module helps to establish a foundation for vibration analysis and machine dynamics. It will introduce analytical and graphical methods for mechanism analysis and synthesis.

Compulsory

• Applied Aerodynamics
  This module introduces more advanced concepts of aerodynamics to develop further aircraft wing aerodynamics and Computational Fluid Dynamics (CFD) for the solution of aerodynamic problems. It will provide a flight test experience to students.
• Mechatronics and Control Engineering
  This module introduces knowledge and methods for designing and implementing mechatronic systems for control and robot systems. Students will develop an understanding of modelling dynamic systems using transfer functions and block diagrams by providing a mathematical foundation for control systems analysis, design and performance improvement.
• Aerospace Structures
  This module introduces advanced concepts for the analysis and design of lightweight structures for aerospace vehicles. Students will learn basic principles underpinning modelling of composite materials and basic principles of static and dynamic aero elasticity.
• Sustainable Engineering Management and Practice
  This modules helps to learn pertinent environmental, quality, health & safety issues, and their relevant related regulations, influencing engineering business. Students will develop professional and technical skills to assess and manage these impacts within the framework of industry-recognised Management Systems.
• Aircraft Propulsion
  This module introduces students with the basics of aircraft propulsion systems. It will provide an understanding of the different propulsion systems for subsonic and supersonic flight and understanding of performance parameters of air breathing engines.
• Space Mechanics and Airworthiness
  This module introduces students to aspects of the mechanics of space and orbit flight and fundamental concepts of atmospheric re-entry and atmospheric heating. Students will learn introduction to aircraft airworthiness requirements and regulations and explain how to meet these requirements in aircraft design and manufacture.
• Major Individual Project
  This module provides experience in planning, researching and conducting a major engineering project in the specialised course of study. Students will apply engineering techniques, critically assess the findings, putting forward ideas and drawing conclusions.

Compulsory

• Major Group Project
  The project aims to give experience of design practice and engineering systems design through undertaking a large multidisciplinary project. It aims to develop the necessary skills in design project management and planning, and to enable students to apply these skills in diverse situations.
• Strategy and Business Planning
  This module aims to critically evaluate the strategic positioning of an organisation for strategy decisions, analyse and assess an organizations resources and capabilities, in relation to an organisations strategic direction in order to develop an effective business development plan for an engineering company.
• Current Topics in Aerospace and Advanced CAD
  This module helps students to understand current topics that are relevant to the current and future design or operation of aerospace vehicles and enable students with more advanced features of CAD.
• Advanced Aerodynamics and Propulsion Systems
  This module provides a more advanced understanding of aircraft aerodynamics and introduces advanced theories and tools for analysis of aircraft aerodynamics.

Optional

• Design and Analysis of Aircraft
  This module aims to familiarise students with a range of aircraft, their configurations, operating environments and design issues and provide an ability to identify the key design features of an aircraft, with reference to airframe structure, aerodynamics, propulsion, use of materials, and mission requirements. It will introduce students to fixed-wing aircraft design methodology.
• Design and Analysis of Spacecraft Systems
  This module aims to familiarise students with a range of spacecraft missions, types, operating environments and major design issues and enable students to develop the design of a space system, taking into account relevant design drivers.
• Fluid Structure Interaction and Aeroelasticity
  This module aims to familiarise students with theories and numerical analysis of linear and nonlinear elastic solids and unsteady aerodynamics. It will help students to numerical techniques for coupling the dynamics of fluid flow and structures.
• Spacecraft Dynamics and Propulsion
  This module aims to familiarise students with more advanced concepts about orbital mechanics, develop the basic principles of rigid body dynamics and control for spacecraft vehicles and develop an understanding of the principles of spacecraft propulsion and current technologies.