Module Title: | Aircraft Structural Mechanics and Analysis |
Language of Instruction: | English |
Teaching & Learning Strategies: |
The module will be delivered using lectures, tutorials and laboratory sessions. |
Module Aim: |
To provide the students with the knowledge and skills required for evaluate a range of structures under complex loading condition by analytical and numerical analysis. |
Learning Outcomes |
On successful completion of this module the learner should be able to: |
LO1 |
Analyse complex stresses and strains due to combined loading and loading on oblique plains. |
LO2 |
Plot the stresses and strains at any plane across the field using graphical methods such as Mohr’s circle. |
LO3 |
Apply the theories of elastic failures to composite structures and assymmetric beams. |
LO4 |
Execute the mathematical and physical principles underlying linear static structural Finite Element Analysis (FEA). |
LO5 |
Analyse complex structural problems using commercial FEA software packages. Demonstrate the ability to design a component/assembly and carry out bolted joint analysis using FEA |
LO6 |
Contribute effectively, as an individual or as part of a group, to the planning and realization of investigations in a laboratory environment into the behaviour of structural materials in service. |
Pre-requisite learning |
Module Recommendations
This is prior learning (or a practical skill) that is recommended before enrolment in this module.
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No recommendations listed |
Incompatible Modules
These are modules which have learning outcomes that are too similar to the learning outcomes of this module. |
No incompatible modules listed |
Co-requisite Modules
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No Co-requisite modules listed |
Requirements
This is prior learning (or a practical skill) that is mandatory before enrolment in this module is allowed. |
No requirements listed |
Module Content & Assessment
Indicative Content |
Stress Transformations
*Two-dimensional stress; Stress on oblique planes; Mohr’s circle of stress; Principal stresses.
*Application to combined bending and shear stress in beams, combined bending and torsion in shafts
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Strain Transformations
*Strains on oblique planes; Principal strains; Mohr’s circle of strain; Derivation of principal stresses from principal strains; Strain gauge rosettes
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Theories of Elastic Failure
*Theories of elastic failure for ductile and brittle materials - Rankine, St Venant, Von-Mises, Haigh and Modified Mohr’s theory
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Bending of Asymmetric Sections
*Product second moment of area;
*Neutral axis; Maximum stress
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Finite Element Analysis
Introduction to linear Finite Element static and dynamic analysis for discrete and distributed mechanical and aerospace structures using industry standard software. Theories relating to numerical integration, boundary conditions, element calculations, assembly, solution, error analysis, post processing.
3D FEA of parts and assemblies. Parametric modelling, mesh studies and quality, FEM validation, contact set studies including bolted joints analysis
Introduction to natural frequencies, modal analysis, transient response.
Introduction to optimization and design, sensitivity analysis, integration of FEM with optimization, applications in the design of solids and structures
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Assessment Breakdown | % |
Continuous Assessment | 20.00% |
Practical | 20.00% |
End of Module Formal Examination | 60.00% |
Continuous Assessment |
Assessment Type |
Assessment Description |
Outcome addressed |
% of total |
Assessment Date |
Written Report |
Students will be required to submit an report on topics relating to structural Analysis using FEA. Students will also partake in a group design and analysis project. |
3,4,5,6 |
20.00 |
n/a |
Practical |
Assessment Type |
Assessment Description |
Outcome addressed |
% of total |
Assessment Date |
Practical/Skills Evaluation |
Students will be expected to perform analysis of a part/assembly using FEA software. |
3,4,5 |
20.00 |
n/a |
End of Module Formal Examination |
Assessment Type |
Assessment Description |
Outcome addressed |
% of total |
Assessment Date |
Formal Exam |
Final exam |
1,2,3,4,5 |
60.00 |
End-of-Semester |
SETU Carlow Campus reserves the right to alter the nature and timings of assessment
Module Workload
Workload: Full Time |
Workload Type |
Frequency |
Average Weekly Learner Workload |
Lecture |
12 Weeks per Stage |
4.00 |
Laboratory |
12 Weeks per Stage |
4.00 |
Independent Learning Time |
15 Weeks per Stage |
10.27 |
Total Hours |
250.00 |
Module Delivered In
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