Module Descriptors

This module intends to introduce students to the broad but specific overview of the aircraft design and performance configurations and its aerodynamic characteristics. In particular the configuration and sizing of wing design in terms of aerodynamic design requirements is studied and aspects of its geometric shape and features are studied and analysed. The effect of aircraft (wing) design features on aerodynamic forces are studied with computing and analysing critical design and performance parameters.

Aircraft weight and balance characteristics and techniques to estimate weight and CG position are discussed and students are taught on how to conduct weight and CG analysis. Aircraft stability and control performance characteristics are studied where analytical techniques are used to assess and evaluate the state of an aircrfat stabillity mode.  

Aircraft performance characteristics in terms of equations of motions, flight mission, flight envelope, and flight phases are studied, and fundamental parameters in flight phase configuration are examined. Limited optimization study to determine and analyse efficient design and/or performance configuration is given throughout the last LO.  

Also, students will be introduced to the aspects of aircraft sustainable and green design, such as; low energy consumption and green energy, low emisions, green materials (smart, light weight, recyclability), etc.

During the course of this module students will develop their UWS Graduate Attributes (https://www.uws.ac.uk/current-students/your-graduate-attributes/);

Universal: academic atributes (critical thinking and analytical & inquiring mind).

Work-Ready: academic attributes (knowledge of aircraft design and performance and relevant ICT skills, problem solving).

Successful: academic attribute (autonomous); personal attribute (resilient); professional attribute (driven).

• This module has been reviewed and updated, taking cognisance of the University’s Curriculum Framework principles. Examples of this are found within the module such as active and engaging laboratory and tutorial activity, module assessment which reflects industry design activities, learning synergies across modules and levels of study, recorded lecture content supporting students to organise their own study time and the use of real-world aircraft design specifications utilising digital solutions supporting assessment authenticity and development of digital intelligence meta-skills.

On successful completion of this module the student will be able to:

L1. Analyse aircraft wing design configuration and the impact they have on aerodynamic forces

L2. Analyse and estimate aircraft weight and balance and CG position

L3. Appraise aircraft performance throughout the operational envelope

L4. Examine aircraft design and performance configuration layout and optimisation

A critical knowledge and understanding of aerodynamics and aircraft performance and its importance in aircraft design.

Specific and detailed knowledge and understanding of the application, techniques and practices associated with aerodynamics and aircraft performance.

Using aerodynamics calculation tools to solve engineering and design problems.

Applying knowledge and understanding to analyse aerodynamic and aircraft performance problems.

Performing wind tunnel testing on aerofoil sections to establish how aircraft wings behave during a typical flight phase.

Assessing a wide range of aircraft configurations and deciphering reasons for designing aircraft in this manner from an aerodynamics perspective.

Select and apply appropriate computational and analytical techniques to model complex problems, discussing the limitations of the techniques employed

Select and critically evaluate technical literature and other sources of information to solve complex problems.

Apply an integrated or systems approach to the solution of complex problems.

In relation to aircraft design and performance evaluate the environmental and societal impact of solutions to complex problems (to include the entire life-cycle of a product or process) and minimise adverse impacts.

Undertaking, evaluating and assessing analysis of aerodynamics problems. Making judgements on analytical data and results. Being able to develop conceptual solutions and strategies to solve problems.

Detailing results data and making critical comparative assessments between theoretical and experimental predictions.

Bringing information together from a variety of sources during problem solving and being able to explain potential problems with methods and strategies.

Ability to perform, interpret and evaluate complex numerical, geometrical and graphical data and using it to solve problems associated with aerodynamics and aircraft performance.

Ability to derive and solve complex equations. Making use of research literature to find solutions to problems and make use of experimental techniques.

Using communications skills to write detailed, critical technical reports, including text and illustration.

Identifying and addressing their own learning needs both during and out with class time.

Identifying solution routes and strategies using their own initiative and informed judgments.

The following materials form essential underpinning for the module content and ultimately for the learning outcomes:

In line with the Academic Engagement Procedure, Students are defined as academically engaged if they are regularly engaged with timetabled teaching sessions, course-related learning resources including those in the Library and on the relevant learning platform, and complete assessments and submit these on time. Please refer to the Academic Engagement Procedure at the following link: Academic engagement procedure

2.14

1. More than one assessment method can be used to assess individual learning outcomes.
2. Schools are responsible for determining student contact hours. Please refer to University Policy on contact hours (extract contained within section 10 of the Module Descriptor guidance note).
   This will normally be variable across Schools, dependent on Programmes &/or Professional requirements.