Course Title: Stress 2

Part B: Course Detail

Teaching Period: Term2 2011

Course Code: AERO5400

Course Title: Stress 2

School: 130T Engineering (TAFE)

Campus: City Campus

Program: C6011 - Advanced Diploma of Engineering (Aerospace)

Course Contact : Program Manager

Course Contact Phone: +61 3 9925 4468

Course Contact Email:engineering-tafe@rmit.edu.au


Name and Contact Details of All Other Relevant Staff

Course Teacher: Yadana Wai
Contact Details: Location: City Campus 57.5.20
Telephone: 9925 4461
Email: yadana.wai@rmit.edu.au

Nominal Hours: 80

Regardless of the mode of delivery, represent a guide to the relative teaching time and student effort required to successfully achieve a particular competency/module. This may include not only scheduled classes or workplace visits but also the amount of effort required to undertake, evaluate and complete all assessment requirements, including any non-classroom activities.

Pre-requisites and Co-requisites

AERO5390 Stress 1

Course Description

The purpose of this course is to provide training in aerospace engineering structural analysis concepts and computations for para-professional technicians.
This course focuses on structural analysis concepts for the para-professional technician in solid mechanics. Areas covered include: strain, shear, bending, torsion stress, concentration, fatigue and design.


National Codes, Titles, Elements and Performance Criteria

National Element Code & Title:

VBH733 Stress 2


Learning Outcomes


1. Analyse and explain strain energy.
2. Analyse and explain aspects of axial force and deformation.
3. Analyse and explain aspects of shear force and deformation.
4. Analyse and explain aspects of stresses within thin walled pressure vessels and perform related calculations.
5. Explain, analyse and perform calculations relating to beam bending stresses and curvature.
6. Analyse and perform calculations relating to beam shear stress.
7. Analyse, explain and perform calculations relating to shear stress and strain in members under torsional load.
8. Explain, analyse and perform calculations relating to two dimensional stresses.
9. Explain, analyse and perform calculations relating to two dimensional strain.
10. Explain, analyse and perform calculations relating to the stress-strain relationship in a two dimensional stress system.
11. Explain, analyse and perform calculations relating to stresses in joints.
12. Analyse and perform calculations relating to the deflecting of beams.
13. Explain, analyse and perform calculations relating to column instability and building.
14.Perfom calculations and experiments relating to the concentration of stresses and explain related concepts.
15. Explain the process of metal fatigue and perform fatigue life calculations.
16. Research and explain aspects of aircraft design.



Details of Learning Activities

Course Description
The purpose of this module is to provide competency based training in aerospace engineering structural analysis concepts and computation for para-professional technicians.
The delivering mode consists of lectures, classroom based exercises and tutorials.
This module facilitates articulation into Aerospace and Engineering degree courses.


Teaching Schedule

Course Schedule
This course involves the delivery over 17 weeks using the following tentative format: 

Session 1 : Stress 1 Revision & Beam Theory

Session 2: Stress 1 Revision & Beam Theory

Session 3: Axial force and deformation 

Session 4: Shear force and deformation

Session 5: Worksheet 1

Session 6: Beam Deflection

Session 7: Beam Deflection & Worksheet 2

Session 8: Torsion of Circular & Non-Circular Shafts

Session 9: Stresses and Strains in Thin-Walled Pressure Vessels – Worksheet 3

Session 10: Unit Test No. 1

Session 11: Stress & Strain in Compound Bars & Thermal Stress & Strain.

Session 12: Strain Energy & Impact Loads. Rivets & Welds. Buckling of Columns

Session 13: Bucking of Columns – Worksheet 4

Session 14: Combined Stresses in a 2D Stress System/Mohr’s Circle

Session 15: Unit Test No. 2

Session 16: Course Revision

Session 17: FINAL EXAMINATION

Please note: While your teacher will cover all the material in this schedule, the weekly teaching and assessment order is subject to change depending on class needs and availability of resources.



Learning Resources

Prescribed Texts

Engineering Mechanics Statics R.C. Hibbler (Any version)
Statics and Mechanics of materials Ferdinand P. Beer, E. Russell Johnston, John T. Dewolf and David F. Mazurek
Vector Mechanics for Engineers Beer, E. Russell Johnston and E. Clausen
Engineering Mechanics and Strength of Materials Roger Kinsky

Class notes and tutorials


References

Bolton, W., Mechanical Science., Blackwell Scientific Publications., ISBN 063203579X

Benham, P.P. and Warnock F.V., Mechanics of Solids and Structures

Hall, A.S. An Introduction to the Mechanics of Solids

Olsen, G.A. Elements of Mechanics of Materials

Shigley, J.E. and Mitchell, L.D. Mechanical Engineering Design

Megson, T.H.G Aircraft Structures

Rivello, Robert M. Theory and Analysis of Flight Structures

Fenner, Roger T. Mechanic of Solids

Hannah, J. and Hillier, M.J. Applied Mechanics

Timoshenko, S.P. and Gere, M. Mechanics of Solids, S1 Edition


Other Resources

Class notes, Tutorials and Worksheets.


Overview of Assessment

To successfully complete this course the student is required to pass written assessment tasks and demonstrate skills and ability by completing pratical tasks to aerospace standard.


Assessment Tasks

Assessment (2011)

Assessment Item 1 (10%): TEST 1
Assessment Item 2 (10%): TEST 2
Assessment Item 3 (30%): ASSIGNMENT
Assessment Item 4 (50%): EXAMINATION

Grading Criteria
NN 0-49% Fail
PA 50 – 59% Pass
CR 60 – 69% Credit
DI 70 – 79% Distinction
HD 80-100% High Distinction

The student will be assessed in various methods to ensure that the requirements of the course are met. Successful graduation from the course is achieved when the candidate attains at least 50% of the total marks AND the student needs to achieve a minimum of 50% for each asessment tasks.

Academic Misconduct (Plagiarism)
Plagiarism is a form of cheating and it is very serious academic offence that may lead to expulsion from the University. Please Refer: www.rmit.edu.au/academicintegrity



Assessment Matrix

Assessment Method Learning Outcomes Percentage
Test One  1 to 6 10%
Test Two  7 to 13 10%
Assignment  14, 15 and 16 30
Final Exam  1 to 13 50

Course Overview: Access Course Overview