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Undergraduate Programme Specification

BEng Aerospace Engineering with International Year One (Sandwich)

Academic Year 2021/22

A programme specification is required for any programme on which a student may be registered. All programmes of the University are subject to the University's Quality Assurance processes. All degrees are awarded by Queen's University Belfast.

Programme Title BEng Aerospace Engineering with International Year One (Sandwich) Final Award
(exit route if applicable for Postgraduate Taught Programmes)
Bachelor of Engineering
Programme Code AE-BENG-SI UCAS Code HECoS Code 100115 - Aerospace engineering - 100
ATAS Clearance Required No
Mode of Study Full Time
Type of Programme Single Honours Length of Programme Full Time - 4 Academic Year(s) Total Credits for Programme 480
Exit Awards available

Institute Information

Teaching Institution

Queen's University Belfast

School/Department

Mechanical & Aerospace Engineering

Quality Code
https://www.qaa.ac.uk/quality-code

Higher Education Credit Framework for England
https://www.qaa.ac.uk/quality-code/higher-education-credit-framework-for-england

Level 6

Subject Benchmark Statements
https://www.qaa.ac.uk/quality-code/subject-benchmark-statements

The Frameworks for Higher Education Qualifications of UK Degree-Awarding Bodies
https://www.qaa.ac.uk/docs/qaa/quality-code/qualifications-frameworks.pdf

Engineering (2019)

Accreditations (PSRB)

Regulation Information

Does the Programme have any approved exemptions from the University General Regulations
(Please see General Regulations)

None

Programme Specific Regulations

Criteria for Admissions

The programme is offered to International (OS fee status) Students only.
There are two intakes into Year One, in September and in January of an academic year.
English Language Requirements:
Candidates will normally be required to have an English Language test score at CEFR B2 Level taken within the last two years.
Academic Subject Requirements:

Internationally Recognised Examinations
Two D Grades from a UK A-Level Board or equivalent to include Mathematics and at least one from Physics (preferred), Biology, Chemistry, Further Mathematics, Technology and Design or Double Award Applied Science.
First Year pass at an overseas university with good grades.
Students with SAT: 2 Advanced Placements at Grade 3 or higher.
Completion of the International Baccalaureate with minimum of 24 points.
All students must hold an (I) GSCE grade C Mathematics or equivalent.
Entry requirements on a country-by-country basis are given in Appendix 1.
Progression from Foundation Programmes:
Students who achieve two D grades (including Mathematics and at least one from Physics (preferred), Biology, Chemistry, Further Mathematics, Technology and Design or Double Award Applied Science. in the Queen’s International Foundation Programme in Engineering and Science may progress on to the Degree programme with an International Year One.
Other similar foundation programmes may be acceptable and will be considered on an individual basis.

Criteria for Progression from International Year One to Stage 2

Students must attain 120 CAT points by passing all modules and meet the following criteria:

English Language and Study Skills Module (20 CATs)

minimum of 50% overall (equivalent to IELTS 6.0) minimum of 40% (equivalent to IELTS 5.5) in all components (speaking, listening, reading, writing)
Academic Modules (100 CATs)

A minimum average of 60% across 10 academic modules with passes in 10 out of 10 modules.


Module Attempts

Each opportunity a student has to complete an assessment is counted as an attempt. So, for example, a May exam and an August resit during the same academic year would be counted as two attempts. Students that elect to miss an opportunity will be recorded as Absent and will still have it counted as an attempt. If the Board of Examiners approves an application for consideration of exceptional circumstances, submitted for a missed assessment, this will not be counted as an attempt.

The number of times a student can attempt a module is subject to the following limits:


International Year One and Stage 2 & 3 modules: 2 attempts


Transfer to the sandwich programme

Students may transfer to the corresponding sandwich programme if they have secured an appropriate one-year placement by 31st August.

In the case students on a study visa, this can only be actioned on confirmation from ISS that a appropriate visa is in place.

Transfer to MEng programme

Transfer between BEng and MEng can take place after Stage 2.

BEng students will normally be considered for transfer to the corresponding MEng programme when they have:

• passed all International Year 1 and Stage 2 modules;
• obtained an overall weighted average mark of at least 55% after Stage 2

Average marks will be rounded to the nearest integer. Students who pass at resit will have these marks capped at 40% for the calculation of averages.

Students considered to have reached an appropriate academic standard will be invited to transfer before the start of Stage 3. Students who do not wish to transfer are under no obligation to do so.


Graduating with a BEng honours degree

In addition to the minimum 320 credit requirement (+120 credit placement year) , a student must also pass a major individual project to graduate with a BEng (Hons) degree. The project module must contribute to the degree classification and failure or absence of the individual project may result in the award of an Ordinary degree.

The classification of a BEng honours degree is based on a weighted average mark:

mark = 1/3*(Stage 2) + 2/3*(Stage 3)


Placement Year

The BEng placement is normally undertaken between Stage 2 and Stage 3

In order to be eligible for the award of BEng (Hons) in Aerospace Engineering, students must additionally complete the Cranfield Flight Laboratory module AER2099

Students with protected characteristics

N/A

Are students subject to Fitness to Practise Regulations

(Please see General Regulations)

No

Educational Aims Of Programme

542985To produce graduates who will:
• be pragmatic, taking a systematic approach and the logical and practical steps necessary for, often complex, concepts to become reality;
• seek to achieve sustainable solutions to problems and have strategies for being creative, innovative and overcoming difficulties by employing their skills, knowledge and understanding in a flexible manner;
• be skilled at solving problems by applying their numerical, computational, analytical and technical skills, using appropriate tools;
• be risk, cost and value-conscious, and aware of their social, cultural, environmental, health and safety, and wider professional responsibilities;
• be familiar with the nature of business and enterprise in the creation of economic and social value;
• appreciate the global dimensions of engineering, commerce and communication;
• be able to formulate and operate within appropriate codes of conduct, when faced with an ethical issue;
• be professional in their outlook, capable of team working, effective communicators, and able to exercise responsibility and sound management approaches;
• have significant experience of working in a professional engineering environment.

• be pragmatic, taking a systematic approach and the logical and practical steps necessary for, often complex, concepts to become reality;

• seek to achieve sustainable solutions to problems and have strategies for being creative, innovative and overcoming difficulties by employing their skills, knowledge and understanding in a flexible manner;

• be skilled at solving problems by applying their numerical, computational, analytical and technical skills, using appropriate tools;

• be risk, cost and value-conscious, and aware of their social, cultural, environmental, health and safety, and wider professional responsibilities;

• be familiar with the nature of business and enterprise in the creation of economic and social value;

• appreciate the global dimensions of engineering, commerce and communication;

• be able to formulate and operate within appropriate codes of conduct, when faced with an ethical issue;

• be professional in their outlook, capable of team working, effective communicators, and able to exercise responsibility and sound management approaches;

• have significant experience of working in a professional engineering environment.

Learning Outcomes

Learning Outcomes: Cognitive Skills

On the completion of this course successful students will be able to:

Select and apply appropriate mathematical, experimental and computational techniques for modelling and analysis of engineering problems.

Teaching/Learning Methods and Strategies

The ability to select and apply appropriate mathematical, experimental and computational techniques for modelling analysis of engineering problems is developed and nurtured throughout the course through a range of abstract and applied engineering analysis problems.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work.

Use scientific principles in the development of engineering solutions to practical problems.

Teaching/Learning Methods and Strategies

At each level (Stage 1 – 3) students are given examples in all engineering courses on the application of appropriate tools to engineering problems. Problem solving pervades the degree with each individual discipline emphasising particular aspects.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work.

Use scientific principles in the modelling and analysis of engineering systems, processes and products.

Teaching/Learning Methods and Strategies

Engineering problems commonly encountered in Aerospace will emphasise modelling and solution of problems using closed form and numerical methods.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work.

Select and apply appropriate computer based methods for modelling and analysing engineering problems.

Teaching/Learning Methods and Strategies

Students are introduced through formal taught modules to a variety of computational methods for the solution of engineering problems, including Finite Element Analysis, Computational Fluid Dynamics and Computer Aided Design methods.

Methods of Assessment

Practical, Continuous Assessment, Project Work.

Analyse systems, processes and components requiring engineering solutions.

Teaching/Learning Methods and Strategies

Students are introduced to common Aerospace systems and components through formal lectures in Propulsion, Aircraft Systems Engineering, Aircraft Structures, Flight Mechanics, Aerodynamics and Design, with supporting methods of for analysis of increasing fidelity introduced and examined at each stage of the course.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work.

Create new processes or products through synthesis of ideas from a wide range of sources.

Teaching/Learning Methods and Strategies

Students are introduced to the concepts requirements analysis and trade studies through both formal lectures and through aligned case studies and project work.

Methods of Assessment

Practical, Continuous Assessment, Project Work.

Evaluate commercial risk

Teaching/Learning Methods and Strategies

The concepts of risk and risk mitigation are developed in theory through Aircraft Design and Professional Studies modules, and applied within the context of practical engineering design activities in Aircraft Design 2 and Projects.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work.

Produce solutions to problems through the application of engineering knowledge and understanding.

Teaching/Learning Methods and Strategies

Through engineering problem solving, students are required to demonstrate multidisciplinary problem solving skills, including technical, commercial, legal and environmental impact of design. All MEng students participate in the Group Design project Aircraft Design 3, which requires all of these elements to be included in the final design specification.

Methods of Assessment

Practical, Continuous Assessment, Project Work.

Learning Outcomes: Knowledge & Understanding

On the completion of this course successful students will be able to:

Demonstrate competence in the application of numerical, experimental and computational methods

Teaching/Learning Methods and Strategies

Acquisition is through a combination of lectures, tutorials, practical exercises and course work in Stages 1 and 3.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work.

Understand the underpinning sciences of aeronautics; basic and applied

Teaching/Learning Methods and Strategies

Acquisition is through a combination of lectures, tutorials, practical exercises, laboratory, flight test and project work in Stages 1 – 3.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work

Understand and apply principles of ITC relevant to Aerospace Engineering

Teaching/Learning Methods and Strategies

Acquisition of ITC is achieved throughout the course through exercises and projects for relevant disciplines.

Methods of Assessment

Practical, Continuous Assessment, Project Work

Apply general principles of design to both Aerospace and general engineering project work

Teaching/Learning Methods and Strategies

General principles of design form an integral part of the course in all stages, through both taught modules to understand design principles and applied design project work (both individual and group).

Methods of Assessment

Practical, Continuous Assessment, Project Work

Understand the characteristics of engineering materials and components used in Aerospace

Teaching/Learning Methods and Strategies

Characteristics of engineering materials are introduced in Stage 1 through lectures, tutorials and laboratory work, with this theme followed through to Aircraft Structures 2 and 3.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work

Understand management and business practices (including finance, law, marketing, personnel and quality)

Teaching/Learning Methods and Strategies

The acquisition of knowledge and understanding in management and business practices and related subjects (is achieved through lectures and project work at Stages 2 and 3, underpinned through Professional Studies 2 and 3.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work

Demonstrate understanding of the professional and ethical responsibilities including the global and social context of engineering

Teaching/Learning Methods and Strategies

Students undertake formal taught modules in Professional Studies to gain appreciation of the professional and ethical responsibility of the professional engineer, and are required to demonstrate these principles through project work. Throughout the course students are encouraged to undertake independent reading both to supplement and consolidate what is being taught and learnt and to broaden their knowledge and understanding of the subject.

Methods of Assessment

Written Examination, Project Work

Understand manufacturing and/or operational practice

Teaching/Learning Methods and Strategies

Manufacturing and operational practice are introduced to students through lectures in Manufacturing Technology, Aircraft Design 2 and Manufacturing 3, and project work throughout the course.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work

Understand and apply codes of practice and the regulatory framework

Teaching/Learning Methods and Strategies

Acquisition is achieved through design projects at stages 2 and 3, where specifications for student design are required to be based on FAR/JAR Regulations. Regulations pertaining to Health and Safety, Employment are introduced through Professional Studies modules in Stages 2 and 3.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work

Understand and implement requirements of safe operation

Teaching/Learning Methods and Strategies

Practical skills form a core part of the degree programme, in keeping with the CDIO approach to engineering education, with a wide range of laboratory and practical design exercises embedded through the programme from Level 1 to Level 3 in order to understand and demonstrate principles of safe operation.

Methods of Assessment

Practical, Continuous Assessment, Project Work

Learning Outcomes: Subject Specific

On the completion of this course successful students will be able to:

Demonstrate skills in the use of appropriate mathematical methods for modelling and analysing discipline-specific engineering problems.

Teaching/Learning Methods and Strategies

Skills in are developed in individual disciplines where lectures, examples and laboratory work reinforce basic principles.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work

Use relevant test and measurement equipment.

Teaching/Learning Methods and Strategies

Laboratories are used to reinforce learning at each stage, covering core competencies through the Laboratory programme in Stage 1, and further reinforced by subject specific laboratory work at Stages 2 and 3.

Methods of Assessment

Practical, Continuous Assessment, Project Work

Use engineering IT tools (including programming languages where appropriate)

Teaching/Learning Methods and Strategies

Students are formally introduced to the principles and use of a range of IT tools, including Microsoft products, VBA, Matlab, CFD, FEA and CAD, as well as other specialist software as required.

Methods of Assessment

Practical, Continuous Assessment, Project Work

Design systems, components or processes.

Teaching/Learning Methods and Strategies

Students undertake a number of design exercises at each stage of the course in order to develop and refine design skills through practical group case studies.

Methods of Assessment

Practical, Continuous Assessment

Test design ideas in laboratory or through simulation, with technical analysis and critical evaluation of results

Teaching/Learning Methods and Strategies

Aircraft design projects provide opportunities to test concepts first through analysis and simulation, and extended to physical test through Design-Build-Fly activities.

Methods of Assessment

Practical, Continuous Assessment

Research for information to develop ideas further.

Teaching/Learning Methods and Strategies

Students are introduced to the concepts of literature survey and research methods formally through Project 3B.

Methods of Assessment

Practical, Continuous Assessment, Project Work

Project management.

Teaching/Learning Methods and Strategies

Students are expected to demonstrate project management skills through all project and group work throughout the course, including development of Gantt charts, work allocation models, work package planning, risk assessment, cost analysis and reporting.

Methods of Assessment

Project Work

Learning Outcomes: Transferable Skills

On the completion of this course successful students will be able to:

Manipulate and sort data

Teaching/Learning Methods and Strategies

Manipulation and sorting of data and presentation of data is illustrated and practiced through laboratory work, worked examples and tutorial problems, through all levels in the course.

Methods of Assessment

Practical, Continuous Assessment, Project Work.

Present data in a variety of ways

Teaching/Learning Methods and Strategies

Presentation of data is required at all levels of the course, both through written laboratory reports and technical documents through to oral presentations and interviews.

Methods of Assessment

Practical, Continuous Assessment, Project Work.

Use scientific evidence based methods in the solution of problems

Teaching/Learning Methods and Strategies

Use of scientific based methods is taught at all levels and all courses. This is achieved through worked examples, lectures, tutorials and laboratory work.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work.

Use general IT tools

Teaching/Learning Methods and Strategies

Competence in the use of IT tools is achieved initially through lectures and practical work in Stage 1 and 2 and is developed through small focused projects in other subjects.

Methods of Assessment

Practical, Continuous Assessment, Project Work.

Use creativity and innovation in problem solving

Teaching/Learning Methods and Strategies

Creativity and problem resolution with contradictory information is attained predominantly through the design courses embedded in Stages 1 to 3. At Stage 1 this relates to a smaller focused design problem but is developed through the stages via design projects for complete aircraft with broad specifications or in fields about which little is currently known.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work.

Work with limited or contradictory information

Teaching/Learning Methods and Strategies

Worked examples are used to illustrate the engineering approach to the solution of problems and students are encouraged in this way throughout the course.

Methods of Assessment

Written Examination, Practical, Continuous Assessment, Project Work.

Communicate effectively

Teaching/Learning Methods and Strategies

Students are required to demonstrate their competence in communicating their ideas to a range of different audiences through their degree, ranging from written through to verbal communication, and to be able to understand what is most appropriate for the task in question.

Methods of Assessment

Practical, Continuous Assessment, Project Work.

Demonstrate key lifelong learning skills

Teaching/Learning Methods and Strategies

Through project and group work embedded at all stages of the programme, students develop skills in time management, project management, teamwork and leadership which are readily transferrable to all sectors. Challenging problems which require multidisciplinary approaches also engender the need for lifelong learning.

Methods of Assessment

Practical, Continuous Assessment, Project Work.

Learning Outcomes: Subject Specific

On the completion of this course successful students will be able to:

Have demonstrated necessary competency in the use of English at Year One

Teaching/Learning Methods and Strategies

Students study the module English Language and Study Skills in International Year One 1 in order to develop their proficiency in reading, writing, speaking and listening in the English Language to the level necessary to progress to Stage 2.
Written presentations are also embedded in the International Year 1 modules and are integrated with the aims of the English Language and Study Skills module. All International Year 1 academic modules are taught in small classes with specific instruction in the vocabulary and use of English appropriate to each academic module.

Methods of Assessment

Unseen examinations in speaking, listening, reading and writing in English
Written laboratory reports and essays
Reading Logs
Group project oral presentation
Listening coursework assignments

Unseen written examinations
Written laboratory reports

Module Information

Stages and Modules

Module Title Module Code Level/ stage Credits

Availability

Duration Pre-requisite

Assessment

S1 S2 Core Option Coursework % Practical % Examination %
English Language and Study Skills NTO1001 1 20 YES YES 24 weeks N YES 40% 0% 60%
Dynamics NTO1014 1 10 YES YES 12 weeks N YES 20% 0% 80%
Fluid Mechanics NTO1015 1 10 YES YES 12 weeks N YES 40% 0% 60%
Structural and Stress Analysis NTO1016 1 10 YES YES 12 weeks N YES 20% 0% 80%
Thermodynamics NTO1018 1 10 YES YES 12 weeks N YES 20% 0% 80%
Engineering Mathematics 1 NTO1026 1 10 YES YES 12 weeks N YES 20% 0% 80%
Engineering Mathematics 2 NTO1027 1 10 YES YES 12 weeks N YES 40% 0% 60%
Drawing and Design NTO1040 1 10 YES YES 12 weeks N YES 100% 0% 0%
Mechanical Principles NTO1042 1 10 YES YES 12 weeks N YES 40% 0% 60%
Materials and Manufacture NTO1043 1 10 YES YES 12 weeks N YES 40% 0% 60%
Aerospace Principles NTO1050 1 10 YES YES 12 weeks N YES 20% 80% 0%
Professional Studies 2 MEE2005 2 10 YES 12 weeks N YES 100% 0% 0%
Aircraft Structures 2 AER2009 2 20 YES YES 24 weeks N YES 20% 0% 80%
Mathematics and Computing 2 MEE2029 2 20 YES YES 24 weeks N YES 100% 0% 0%
Manufacturing Technology 2 MEE2034 2 10 YES YES 24 weeks N YES 100% 0% 0%
Employability 2 MEE2098 2 0 YES 12 weeks N YES 100% 0% 0%
Laboratory Programme 1 MEE1011 2 0 YES YES 2 weeks N YES 50% 50% 0%
Aircraft Design 2 AER2013 2 20 YES YES 24 weeks N YES 100% 0% 0%
Aircraft Aerodynamics and Performance 2 AER2007 2 20 YES YES 24 weeks N YES 50% 0% 50%
Compressible Flow and Propulsion 2 AER2008 2 20 YES YES 24 weeks N YES 50% 0% 50%
Aerospace Flight Laboratory AER2099 2 0 YES 1 weeks N YES 100% 0% 0%
Placement Year MEE3099 3 120 YES YES 30 weeks N YES 100% 0% 0%
Avionic Systems 3 ELE3030 4 10 YES 12 weeks N YES 19% 0% 81%
Professional Studies 3 MEE3002 4 10 YES 12 weeks N YES 100% 0% 0%
Project 3B MEE3030 4 40 YES YES 24 weeks N YES 100% 0% 0%
Aeronautical Engineering 3 AER3008 4 20 YES YES 24 weeks N YES 60% 0% 40%
Computer-Aided Engineering 3 MEE3013 4 20 YES YES 24 weeks N YES 100% 0% 0%
Manufacturing 3 MEE3014 4 20 YES YES 24 weeks N YES 50% 0% 50%

Notes