Course title
4M5450001
Solid Mechanics

 sakaue kenichi Click to show questionnaire result at 2019
Course content
This course deals with elasticity for the basis of mechanics of materials, the theory of plasticity, the theory of viscoelasticity, fracture mechanics and strength of materials.
Purpose of class
The purpose of this class is comprehensive understanding the advanced knowledge of mechanics of materials basis on continuum mechanics.
Goals and objectives
  1. To understand the basic equations of elasticity.
  2. To understand the behavior of plastic materials and viscoelastic materials.
  3. To understand the basic concept of fracture mechanics.
Language
Japanese
Class schedule

 Class schedule HW assignments (Including preparation and review of the class.) Amount of Time Required
1. Applied mathematics, Tensor analysis Review the lectures 190minutes
2. Stress concept: Stress tensor, Equilibrium of stress, Principal stress, Stress invariants, Deviator stress Review the lectures 190minutes
3. Strain concept 1: Deformation gradient tensor, Cauchy-Green deformation tensor, Strain tensor Review the lectures 190minutes
4. Strain concept 2: Strain tensor, Compatibility equations Review the lectures 190minutes
5. Elasticity 1: Elastic constitutive equations, Elastic moduli, Relationship between elastic moduli Review the lectures 190minutes
6. Elasticity 2: Plane stress, Plane strain, Principle of virtual work Review the lectures 190minutes
7. Elasticity 3: wo-dimensional stress analysis, Stress function Review the lectures 190minutes
8. Plasticity 1: Plastic deformation, Yield conditions Review the lectures 190minutes
9. Plasticity 2: Equivalent stress, Equivalent plastic strain, Elasto-plastic constitutive equation Review the lectures 190minutes
10. Viscoelasticity 1: Mechanical model for viscoelastic media, Viscoelastic constitutive equation, Viscoelastic characteristics Review the lectures 190minutes
11. Viscoelasticity 2: Viscoelastic stress analysis, Correspondence principle, Rheology Review the lectures 190minutes
12. Fracture mechanics 1: Stress field around a crack tip, Stress intensity factor, Energy release rate Review the lectures 190minutes
13. Fracture mechanics 2: Small scale yielding, J-integral, Cohesive model Review the lectures 190minutes
14. Final exam and review Review the lectures 190minutes
Total. - - 2660minutes
Relationship between 'Goals and Objectives' and 'Course Outcomes'

 Final exam report Total.
1. 25% 10% 35%
2. 25% 10% 35%
3. 23% 7% 30%
Total. 73% 27% -
Evaluation method and criteria
Final grade is determined by reports 27% and final exam 73%.
At least 60 points out of 100 is needed to pass.
Textbooks and reference materials
S.P. Timoshenko and J.N. Goodier, Theory of Elasticity 3rd edition.
Prerequisites
Basic knowledge of mechanics of materials.
Office hours and How to contact professors for questions
  • From 16:00 to 17:00 on Thursday
Regionally-oriented
Non-regionally-oriented course
Development of social and professional independence
  • Course that cultivates a basic problem-solving skills
Active-learning course
N/A
Course by professor with work experience
Work experience Work experience and relevance to the course content if applicatable
N/A N/A
Education related SDGs:the Sustainable Development Goals
  • 9.INDUSTRY, INNOVATION AND INFRASTRUCTURE
Last modified : Sat Mar 21 13:10:17 JST 2020