MTU Courses - CIVL8039 - Advanced Structural Analysis

Module Details

Module Code:	CIVL8039
Title:	Advanced Structural Analysis
Long Title:	Advanced Structural Analysis
NFQ Level:	Advanced
Valid From:	Semester 1 - 2019/20 ( September 2019 )

Duration:	1 Semester

Credits:	5

Field of Study:	5822 - Civil Engineering

Module Delivered in:	2 programme(s)

Module Description:	This module addresses advanced topics in Structural Engineering. Topics such as energy methods, elasticity, dynamic analysis, buckling analysis and analysis of plates and shells are introduced.

Learning Outcomes
On successful completion of this module the learner will be able to:
#	Learning Outcome Description
LO1	Model, analyse and evaluate dynamically loaded simple beams and frames.
LO2	Model, analyse and evaluate elastic plates and shells.
LO3	Model, analyse and evaluate beams using the theory of elasticity.
LO4	Model, analyse and evaluate beams on elastic foundations.
LO5	Model, analyse and evaluate the critical buckling loads of framed structures.
LO6	Model, analyse and evaluate beams, frames, trusses and arches using energy methods.

Dependencies
Module Recommendations This is prior learning (or a practical skill) that is strongly recommended before enrolment in this module. You may enrol in this module if you have not acquired the recommended learning but you will have considerable difficulty in passing (i.e. achieving the learning outcomes of) the module. While the prior learning is expressed as named MTU module(s) it also allows for learning (in another module or modules) which is equivalent to the learning specified in the named module(s).

Incompatible Modules These are modules which have learning outcomes that are too similar to the learning outcomes of this module. You may not earn additional credit for the same learning and therefore you may not enrol in this module if you have successfully completed any modules in the incompatible list.
No incompatible modules listed
Co-requisite Modules
No Co-requisite modules listed
Requirements This is prior learning (or a practical skill) that is mandatory before enrolment in this module is allowed. You may not enrol on this module if you have not acquired the learning specified in this section.
No requirements listed

Indicative Content
Dynamic Analysis Introduction; Structures with degrees of freedom; Natural frequencies; forced vibrations; Matrix formulation; Eigenvalues of matrix; Applications.
Elasticity Flexural modulus of thin plates; Plates subjected to edge moments; Laterally loaded plates; Differential equations of equilibrium; Equations of compatibility; Boundary conditions; Membrane stress analysis of shells of revolution and cylindrical shells; Beam on elastic foundations; Applications.
Buckling Forces transmitted by slender members; Differential equilibrium relationships; Singularity functions; Euler buckling load; Elastic stability of flexible columns; Instability as a mode of failure; Plastic buckling; Stability coefficients; Applications.
Energy Methods Elastic energy; Determination of deformations - beams, frames, trusses and arches; Indeterminate structures; Redundants; Flexibility method; Applications.

Assessment Breakdown	%
Module Content & Assessment
Coursework	50.00%
End of Module Formal Examination	50.00%

Assessments

Coursework

Assessment Type	Project	% of Total Mark	25
Timing	Week 3	Learning Outcomes	1
Assessment Description Model, analyse and evaluate dynamically loaded structures including degrees of freedom, natural frequencies, and mode of vibrations. Undertake laboratory experiment and/or computer analysis to compare results with those obtained using traditional calculations. Peer learning to be incorporated by presentation and discussion of results in class.

Assessment Type	Project	% of Total Mark	25
Timing	Week 6	Learning Outcomes	2
Assessment Description Model, analyse and evaluate the behaviour of shell and plate structures. Use both traditional calculation techniques and proprietary software applications to model and analyse shell/thin plate structures. Evaluate outcomes from both approaches to analysis. Peer learning to be incorporated by presentation and discussion of results in class.

End of Module Formal Examination

Assessment Type	Formal Exam	% of Total Mark	50
Timing	End-of-Semester	Learning Outcomes	3,4,5,6
Assessment Description End of semester formal examination.

Reassessment Requirement
Repeat examination Reassessment of this module will consist of a repeat examination. It is possible that there will also be a requirement to be reassessed in a coursework element.

The University reserves the right to alter the nature and timings of assessment

Module Workload

Workload: Full Time
Workload Type	Contact Type	Workload Description	Frequency	Average Weekly Learner Workload	Hours
Lecture	Contact	Presentation of theory and examples	Every Week	3.00	3
Lecturer-Supervised Learning (Contact)	Contact	Problem framing; Problem solving; Project work	Every Week	1.50	1.5
Independent & Directed Learning (Non-contact)	Non Contact	Self directed study	Every Week	2.50	2.5
Total Hours					7.00
Total Weekly Learner Workload					7.00
Total Weekly Contact Hours					4.50

Workload: Part Time
Workload Type	Contact Type	Workload Description	Frequency	Average Weekly Learner Workload	Hours
Lecture	Contact	Presentation of theory and examples	Every Week	3.00	3
Lecturer-Supervised Learning (Contact)	Contact	Problem framing; Problem solving; Project work	Every Week	1.50	1.5
Independent & Directed Learning (Non-contact)	Non Contact	Self directed study	Every Week	2.50	2.5
Total Hours					7.00
Total Weekly Learner Workload					7.00
Total Weekly Contact Hours					4.50

Recommended Book Resources
Module Resources
Amin Ghali, Adam Neville. (2017), Structural Analysis: A Unified Classical and Matrix Approach, 7th. CRC Press, [ISBN: 9781498725064].
Supplementary Book Resources
T.H.G. Megson. (2019), Structural and Stress Analysis, 4th. Butterworth-Heinemann, [ISBN: 9780081025864]. Russell C. Hibbeler. (2016), Structural Analysis in SI Units, 9th. Pearson Education Limited, [ISBN: 9781292089461]. R. C. Coates, M. G. Coutie, F. K. Kong. (1988), Structural analysis, 3rd. Chapman & Hall, [ISBN: 9780412379802]. Martin S. Williams, J D Todd. (2000), Structures: Theory and analysis, 1st. Palgrave, [ISBN: 9780333677605]. David Johnson. (2004), Linear analysis of skeletal structures, 1st. Thomas Telford, [ISBN: 9780727732767].
This module does not have any article/paper resources
Other Resources
IStructE Essential Knowledge Series, David Cormie. (2016), Essential Knowledge Text No.16: Stability, The Institution of Structural Engineers, http://www.istructe.org/resources-centre /essential-knowledge-series/stability IStructE Essential Knowledge Series, Martin Williams. (2016), Essential Knowledge Text No.17: Dynamics, The Institution of Structural Engineers, http://www.istructe.org/resources-centre /essential-knowledge-series/no-17-dynami cs

Programme Code	Programme	Semester	Delivery
Module Delivered in
CR_CSTRU_8	Bachelor of Engineering (Honours) in Structural Engineering	7	Elective
CR_CSTEN_9	Master of Engineering in Structural Engineering	7	Mandatory