The course delivers to the student combined knowledge from different scientific areas in the fields of Materials Technology, Physical Metallurgy and Mechanics of Materials

• Review of fundamental concepts: internal forces, stresses and strains
•  Stress transformations, principal stresses and planes, maximum shear stress
• Elements of elasticity theory: Linear and non linear elasticity, anelasticity, generalized Hooke’s law
• Elements of plasticity theory: flow curve, equivalent stress – strain, yielding criteria (Von Mises, Tresca)
• Crystal microplasticity : dislocations, slip of crystallographic planes, Schmid Law
• Strengthening mechanisms: strain hardening, solid solution strengthening, precipitation hardening, grain boundary strengthening
• Principles of fracture mechanics
• Mechanical behavior under alternating stress (Fatigue)
•  Mechanical behavior und high temperatures (Creep)

Greek:

1. Γ. Χαϊδεμενόπουλος, Α. Κατσαμάς, ‘‘Μηχανική Συμπεριφορά Υλικών’’, σημειώσεις μαθήματος (2004). 

2. Γ.Ν. Χαϊδεμενόπουλος, ‘‘Φυσική Μεταλλουργία’’, Πανεπιστημιακές Εκδόσεις Θεσσαλίας (2000)

3. Θ. Κερμανίδης, ‘‘Αντοχή Υλικών’’, τόμος Ι, Singular Publications (1994).

4. Σπ. Γ. Παντελάκης, Κ. Ι. Τσερπές, «Μηχανική Συμπεριφορά Υλικών», Εκδόσεις Τζιόλα (2016).

5. Ν. Αράβας, «Μηχανική των Υλικών», Τόμος Πρώτος, ,Εκδόσεις Τζιόλα (2014)

English:

1. Dowling, N.E., Mechanical Behavior of Materials: Engineering Methods for

2. Deformation, Fracture, and Fatigue. 2007: Pearson Prentice Hall.

3. 2.F. A. McClintock, A. S. Argon, Mechanical Behavior of Materials, Addison-Wesley

4. Publishing Company Inc. (1996).

5. W. F. Hosford, Mechanical Behavior of Materials, Cambridge University Press, (2005)

– Related Academic Journals:

1. Materials Science and Engineering Α

2. Fatigue and Fracture of Engineering Materials and Structures

3. International Journal of Fatigue

4. Engineering fracture Mechanics

Greek

Lectures, Exercises