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Strength of Materials 1

 ISOGAI, Takeshi
  Requisites  2 credits
【Mechanical and Precision System・1st semester】
19-1-0161-2327

1.
Outline
In this course, following topics are taught:
(1) Stress and strain; Hook’s law; Stress-strain curves
(2) Deformation induced by weight; Stress and deformation induced by centrifugal
 force; Statically indeterminate problems; Thermal stress; Trusses
(3) Bending of beams; Shear force and bending moment; Bending stress;
 Deflection of beams


2.
Objectives
Strength of materials is the application of mechanics to design components of machines and structures. This course aims to teach definitions of stress and strain, stress and deformation of the components under uniaxial loading, and bending of beams, and to provide students with an understanding of the way in which engineers design mechanical components that can meet specified requirements.
3.
Grading Policy
Your overall grade in the class will be decided based on followings:
-  Midterm examnination (20%)
-  Term-end examnination (40%)
-  Report (20%)
-  Mini tests in the lesson (20%)

We will give feedback by returning the previous mini test and comment on the answer during class. In addition to returning the midterm exam, special problems including guidance at the Learning Support Office will be imposed on those who are not performing well in their grade.
4.
Textbook and Reference
Textbook: "Material mechanics" by Seiichiro Seike, Kyoritsu Publishing (1997)
     ISBN 978-4-320-08117-8
Teaching materials: We will original handouts during the class. Binding them to a file is
         reccommended.
Reference book: "Standard Mechanics of Materials" Goichi Nabe et al., Nikkan Kogyo
        Shimbun (2001) ISBN 4-526-047-19-8
        "Exercise on Strength of Materials [New Revised Edition]" Jyuhachi
        Oda, Toshiro Miyoshi, Science Co., Ltd. (2001) ISBN 4-7819-0975-2
5.
Requirements (Assignments)
· Students should practice well on how to handle units and conversion methods in
 dynamics learned in "Physics 1" etc. Please prepare a table of SI units and
 SI prefixes related to mechanics as a preparation for the first lesson and
 bring it to the class.
· Please practice in order to be able to calculate scientific functions such as
 exponential function, logarithm function, trigonometric functions by using
 your own scientific calculator.
· Please read the relevant part of the textbook before each lesson and check the relation
 with the contents of the last lesson. (1 hour)
· After each lesson, please check the contents of the lesson again with help of textbooks
 and handouts distributed during the class. Please answer the examples and problems
 in the handouts. Also tackle the problems in the textbook that are instructed
 in the handouts. By repeatedly practicing, the ability to master the knowledge
 learned will be improved. (2 hours)
· Detailed preparation for the subsequent lessons will be instructed in the class.
6.
Note
· We will do problem exercises during class, so be sure to bring a scientific calculator.
 A scientific calculator is also necessary for the examination.
· Please refrain from entering/leaving the class during classes.
· As a result of the Midterm examination, students who are lack in mathematical skill
 in this course is be judged. These students need to take special training by using
 the Learning Support Office in order to raise the level of basic skills.
7.
Schedule
1. Stress and Strain 1: Engineering necessity of "Strength of material" ,
 Nominal stress, Nominal strain

2. Stress and Strain 2: Shear Stress, Shear Strain, Poisson's Ratio

3. Stress and Strain 3: Stress-Strain Diagram, Hook's Law, Allowable Stress,
  Safety factor


4. Tension and Compression 1: Deformation and stress due to self weight, Simple truss

5. Tension and compression 2: Indefinite problem, Thermal stress

6. Tension and Compression 3 and Summary of First Half: Stress due to Centrifugal
  Force, Summary of lessons from 1st to 6th


7. Midterm exam and introduction of beam problem: Midterm exam (30 minutes),  
  Cantilevered beam, Both end supported beam, Reaction force of beams


8. Shearing force and bending moment of beam 1: Definition and determination of  
  shear force / bending moment


9. Shear force and bending moment of beam 2: Shear force diagram of cantilever beam,   Bending moment diagram of cantilever beam


10. Shear force and bending moment of beam 3: Shear force diagram of beam supported
  at both ends, Bending moment diagram of beam supported at both ends

11. Bending stress of beam 1: Bending theory of beam, Bending stress, Second moment
  of area

12. Bending stress of beam 2: Second moment of area in various shapes, Shear stress
  of beams


13. Deflection of beams 1: Deflection and deflection angle, Deflection of cantilever beam


14. Deflection of beams 2: Deflection of beam supported at both ends


15. Overall summary and Term-end exam
1.
Outline
In this course, following topics are taught:
(1) Stress and strain; Hook’s law; Stress-strain curves
(2) Deformation induced by weight; Stress and deformation induced by centrifugal
 force; Statically indeterminate problems; Thermal stress; Trusses
(3) Bending of beams; Shear force and bending moment; Bending stress;
 Deflection of beams


2.
Objectives
Strength of materials is the application of mechanics to design components of machines and structures. This course aims to teach definitions of stress and strain, stress and deformation of the components under uniaxial loading, and bending of beams, and to provide students with an understanding of the way in which engineers design mechanical components that can meet specified requirements.
3.
Grading Policy
Your overall grade in the class will be decided based on followings:
-  Midterm examnination (20%)
-  Term-end examnination (40%)
-  Report (20%)
-  Mini tests in the lesson (20%)

We will give feedback by returning the previous mini test and comment on the answer during class. In addition to returning the midterm exam, special problems including guidance at the Learning Support Office will be imposed on those who are not performing well in their grade.
4.
Textbook and Reference
Textbook: "Material mechanics" by Seiichiro Seike, Kyoritsu Publishing (1997)
     ISBN 978-4-320-08117-8
Teaching materials: We will original handouts during the class. Binding them to a file is
         reccommended.
Reference book: "Standard Mechanics of Materials" Goichi Nabe et al., Nikkan Kogyo
        Shimbun (2001) ISBN 4-526-047-19-8
        "Exercise on Strength of Materials [New Revised Edition]" Jyuhachi
        Oda, Toshiro Miyoshi, Science Co., Ltd. (2001) ISBN 4-7819-0975-2
5.
Requirements (Assignments)
· Students should practice well on how to handle units and conversion methods in
 dynamics learned in "Physics 1" etc. Please prepare a table of SI units and
 SI prefixes related to mechanics as a preparation for the first lesson and
 bring it to the class.
· Please practice in order to be able to calculate scientific functions such as
 exponential function, logarithm function, trigonometric functions by using
 your own scientific calculator.
· Please read the relevant part of the textbook before each lesson and check the relation
 with the contents of the last lesson. (1 hour)
· After each lesson, please check the contents of the lesson again with help of textbooks
 and handouts distributed during the class. Please answer the examples and problems
 in the handouts. Also tackle the problems in the textbook that are instructed
 in the handouts. By repeatedly practicing, the ability to master the knowledge
 learned will be improved. (2 hours)
· Detailed preparation for the subsequent lessons will be instructed in the class.
6.
Note
· We will do problem exercises during class, so be sure to bring a scientific calculator.
 A scientific calculator is also necessary for the examination.
· Please refrain from entering/leaving the class during classes.
· As a result of the Midterm examination, students who are lack in mathematical skill
 in this course is be judged. These students need to take special training by using
 the Learning Support Office in order to raise the level of basic skills.
7.
Schedule
1. Stress and Strain 1: Engineering necessity of "Strength of material" ,
 Nominal stress, Nominal strain

2. Stress and Strain 2: Shear Stress, Shear Strain, Poisson's Ratio

3. Stress and Strain 3: Stress-Strain Diagram, Hook's Law, Allowable Stress,
  Safety factor


4. Tension and Compression 1: Deformation and stress due to self weight, Simple truss

5. Tension and compression 2: Indefinite problem, Thermal stress

6. Tension and Compression 3 and Summary of First Half: Stress due to Centrifugal
  Force, Summary of lessons from 1st to 6th


7. Midterm exam and introduction of beam problem: Midterm exam (30 minutes),  
  Cantilevered beam, Both end supported beam, Reaction force of beams


8. Shearing force and bending moment of beam 1: Definition and determination of  
  shear force / bending moment


9. Shear force and bending moment of beam 2: Shear force diagram of cantilever beam,   Bending moment diagram of cantilever beam


10. Shear force and bending moment of beam 3: Shear force diagram of beam supported
  at both ends, Bending moment diagram of beam supported at both ends

11. Bending stress of beam 1: Bending theory of beam, Bending stress, Second moment
  of area

12. Bending stress of beam 2: Second moment of area in various shapes, Shear stress
  of beams


13. Deflection of beams 1: Deflection and deflection angle, Deflection of cantilever beam


14. Deflection of beams 2: Deflection of beam supported at both ends


15. Overall summary and Term-end exam