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Course Information
Course Unit Title : Advanced Strength of Materials
Course Unit Code : 01MAK5159
Type of Course Unit : Optional
Level of Course Unit : Second Cycle
Year of Study : Preb
Semester : 255.Semester
Number of ECTS Credits Allocated : 6,00
Name of Lecturer(s) : ---
Course Assistants :
Learning Outcomes of The Course Unit : Upon successful completion of this course, students will

1. Have sufficient solid mechanics background to learn computational methods, and advanced structural mechanics, and designs.
2. Be able to conduct stress analysis of a general structure member, such as beams, plates, joints between different structure parts, etc.
3. Recognize the physical nature and complexity that a structural mechanics problem may involve,
4. Be able to conduct stress analysis of a general structure member, such as beams, plates, joints between different structure parts, etc.
Mode of Delivery : Face-To-Face
Prerequisities and Co-requisities Courses : Unavailable
Recommended Optional Programme Components : Unavailable
Course Contents : Stress, Strain, Equilibrium, Stress-strain relationship and generalized Hooke Law, Plane stress, Plane strain, Airy stress function, Strength theories, Fatigue, Basic plasticity, Thin plates and shells, Fracture mechanics, Visco-Elasticity, Finite Element Method.
Languages of Instruction : Turkish
Course Goals :
Course Aims : This course extends the student’s knowledge of the subjects covered in elementary strength of materials and lays the foundation for follow-on courses such as finite element methods, plasticity theory and fracture mechanics. The basic relationships between stress, strain, and displacements are covered in more depth.
WorkPlacement   Not Available
Recommended or Required Reading
Textbook : There is no required textbook for this course. Course notes will be distributed along with a reading list.
Additional Resources : In addition to the course notes the following textbooks will provide useful background reading: - Cisimlerin Mukavemeti, Prof. Dr. Mehmet Bakioğlu, 2001 - Advanced Strength and Applied Stress Analysis by Richard G. Budynas, 1998 - Advanced Strength and Applied Elasticity, Ansel C. Ugural and Saul K. Fenster, Fourth Edition, Prentice Hall, New Jersey, 2003. - Introduction to Solid Mechanics by Irving H. Shames, 1989 - Classical and Computational Solid Mechanics, Y. C. Fung and P. Tong, World Scientific Publishing Co., Singapore, 2001 - Mechanics of Materials by R.C. Hibbeler, 1991 - Mechanics of Materials by S.P. Timoshenko and James M. Gere, 1972 In addition to these supplemental textbooks, students will be provided selected research papers.
Material Sharing
Documents :
Assignments :
Exams :
Additional Material :
Planned Learning Activities and Teaching Methods
Lectures, Practical Courses, Presentation, Seminar, Project, Laboratory Applications (if necessary)
ECTS / Table Of Workload (Number of ECTS credits allocated)
Student workload surveys utilized to determine ECTS credits.
Activity :
Number Duration Total  
Course Duration (Excluding Exam Week) :
14 3 42  
Time Of Studying Out Of Class :
14 4 56  
Homeworks :
3 5 15  
Presentation :
1 10 10  
Project :
1 15 15  
Lab Study :
0 0 0  
Field Study :
0 0 0  
Visas :
2 10 20  
Finals :
1 10 10  
Workload Hour (30) :
30  
Total Work Charge / Hour :
168  
Course's ECTS Credit :
6      
Assessment Methods and Criteria
Studies During Halfterm :
Number Co-Effient
Visa :
2 60
Quiz :
0 0
Homework :
3 15
Attendance :
0 0
Application :
0 0
Lab :
0 0
Project :
1 15
Workshop :
0 0
Seminary :
1 10
Field study :
0 0
   
TOTAL :
100
The ratio of the term to success :
50
The ratio of final to success :
50
TOTAL :
100
Weekly Detailed Course Content
Week Topics  
1 Definition and analysis of stress
 
2 Definition of strain and stres-strain relationship, Hookes Law
 
3 Generalized Hookes Law, Strain measurement and strain-gages
 
4 Strain energy and Saint-Venant principle
 
5 Two-dimensional elasticity problems, Plane strain problems
 
6 Plane stres problems
 
7 Airy stress functions
 
8 Failure theories
 
9 Fatigue
 
10 Basic Plasticity
 
11 Thin plates and shells
 
12 12 Fracture mechanics
 
13 Visco-elastisity
 
14 Finite element method