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SDÜ Education Information System Course Content
Programme
Graduate School of Natural and Applied Sciences Manufacturing Engineering
Course Information
Course Unit Code
Course Unit Title
Credit Theoretic
Credit Pratic
Credit Lab/A
Credit Total
Credit Ects
Semester
01IMM5106
Elastostatic
3.00
0.00
0.00
3.00
6.00
1
Course Information
Language of Instruction
Turkish
Type of Course Unit
Elective
Course Coordinator
Associate Professor Dr. M.Reşit USAL
Course Instructors
3-Mustafa Reşit Usal
Course Assistants
 
Course Aims
To study mechanical behavior of engineering materials by mathematical methods without simplified assumptions.
Course Goals
1) To show differences between strength of materials and elasticity
2) To define concepts of stress vector and stress tensor
3) To teach concept of principal stress
4) To teach infinitesimal shape changes and strains
5) To teach strain invariants and principal directions
6) To teach states of plane strain and plane stress
7) to show formulation of elasticity problems and its solution methods
Learning Outcomes of The Course Unit
1) Basic definitions of strain and stress tensors
2) Strain-stress relations
3) Plane strain,
4) Plane stress
5) Formulation of elasticity problems.
6) Solution of elasticity problems.
Course Contents
Stress Analysis, Stress at A Point, Principal Stress and Mohr?s Circle in Two Dimension, Stress at A Point, Principal Stress and Mohr?s Circle in Three Dimension, Strain, Stress-Strain Relations and Equations of Compatibility, Transformations of Two and Three Dimensional Strain, Hooke?s Law and Generalized Hooke?s Law, Plane Strain Problems, Plane Stress Problems, Solution of Elasticity Problems, Airy Stress Functions
Prerequisities and Co-requisities Courses
 
Recommended Optional Programme Components
 
Mode Of Delivery
 
Level of Course Unit
 
Assessment Methods and Criteria
ECTS / Table Of Workload (Number of ECTS credits allocated)
Studies During Halfterm
Number
Co-Efficient
Activity
Number
Duration
Total
Visa
1
50
Course Duration (Excluding Exam Week)
14
3
42
Quiz
0
0
Time Of Studying Out Of Class
14
4
56
Homework
10
40
Homeworks
10
4
40
Attendance
1
10
Presentation
0
0
0
Application
0
0
Project
0
0
0
Lab
0
0
Lab Study
0
0
0
Project
0
0
Field Study
0
0
0
Workshop
0
0
Visas
1
12
12
Seminary
0
0
Finals
1
16
16
Field study
0
0
Workload Hour (30)
30
TOTAL
100
Total Work Charge / Hour
166
The ratio of the term to success
40
Course's ECTS Credit
6
The ratio of final to success
60
 
TOTAL
100
 
Recommended or Required Reading
Textbook
 
Additional Resources
A. C. Ugural and S. K. Fenster,1995. Advanced Strength of Materials and Applied Elasticity,

S.P. Timoshenko and J.N. Goodier, 1970. Theory of Elasticity (third ed.), McGraw-Hill Int. Ed., Singapore.

M. İnan, 1969. Düzlem Elastisite Teorisi, Matbaa Teknisyenleri Basımevi, İstanbul.
Elasticity in Engineering Mechanics, 2000. Arthur P. Boresi and Ken P. Chong, John Wiley& Sons.

Mechanics of Deformable Solids, 1999. Issam Doghri, Springer Verlag.
Theory of Elasticity, 1970. S. Timoshenko, J.N. Goodier, McGraw-Hill Education.
Material Sharing
Documents
 
Assignments
 
Exams
 
Additional Material
 
Planned Learning Activities and Teaching Methods
Lectures, Practical Courses, Presentation, Seminar, Project, Laboratory Applications (if necessary)
Work Placements
As with any other educational component, credits for work placements are only awarded when the learning outcomes have been achieved and assessed. If a work placement is part of organised mobility (such as Farabi and Erasmus), the Learning Agreement for the placement should indicate the number of credits to be awarded if the expected learning outcomes are achieved.
Program Learning Outcomes
No
Course's Contribution to Program
Contribution
1
An able to use informations of mathematicall, science, engineeringin solving the manufacturing engineering problems
5