At the end of this course, the students; 1) Learn about advanced strength issues and properties material 2) Perform the mechanical analysis of composite materials 3) Examine the residual and stresses in material 4) Reflect on the region of plastic deformation
MODE OF DELIVERY
Face to face
PRE-REQUISITES OF THE COURSE
No
RECOMMENDED OPTIONAL PROGRAMME COMPONENT
None
COURSE DEFINITION
Properties and structures of materials, Advanced subjects on material strength, Composites, Analysis of honeycomb and reinforced structured materials, Design of pressurized vessel, Residual stresses, Thermal stresses, Breakdown theory, Deformation in plastic region, Bending, Sudden impact and inertia.
COURSE CONTENTS
WEEK
TOPICS
1st Week
Introduction engineering design approach, review of stress, strain and energy methods
2nd Week
Introduction engineering design approach, review of stress, strain and energy methods
3rd Week
Material selection for design
4th Week
Design against failure; Failure theories for various failure modes (large deflection, large permanent deformation,fracture, fatigue, failure under impact, buckling, resonance)
5th Week
Design against failure; Failure theories for various failure modes (large deflection, large permanent deformation, fracture, fatigue, failure under impact, buckling, resonance)
6th Week
Plates and shells
7th Week
Plates and shells
8th Week
Midterm Exam
9th Week
Probabilistic design
10th Week
Probabilistic design
11th Week
Thermal stresses; Residual stresses
12th Week
Plasticity
13th Week
Advanced topics on beams (design of beams, beams on elastic supports)
14th Week
Composite Materials
RECOMENDED OR REQUIRED READING
S Advanced Strength and Applied Elasticity, AC Ugural, SK Fenster, 4th edition, Prentice Hall, 2003 Cisimlerin Mukavemeti, FP Beer, R Johnston, Çeviri: ÖR Akgün, Beta Basım, 2003. Daniel M. Isaac, Ishai Ori (1994), Engineering Mechanics of Composite Materials, NY, Oxford University Press.
