COURSE SYLLABUS

STRENGHT OF MATERIALS I

1	Course Title:	STRENGHT OF MATERIALS I
2	Course Code:	OTO2003
3	Type of Course:	Compulsory
4	Level of Course:	First Cycle
5	Year of Study:	2
6	Semester:	3
7	ECTS Credits Allocated:	4
8	Theoretical (hour/week):	3
9	Practice (hour/week) :	0
10	Laboratory (hour/week) :	0
11	Prerequisites:	None
12	Recommended optional programme components:	None
13	Language:	Turkish
14	Mode of Delivery:	Face to face
15	Course Coordinator:	Prof. Dr. MURAT YAZICI
16	Course Lecturers:	Prof. Dr. ALİ DURMUŞ
17	Contactinformation of the Course Coordinator:	PROF. DR. MURAT YAZICI BURSA ULUDAĞ ÜNİVERSİTESİ MÜHENDİSLİK FAKÜLTESİ OTOMOTİV MÜHENDİSLİĞİ BÖLÜMÜ TR16059 GÖRÜKLE/BURSA/TÜRKİYE TEL: 90(224) 2942630 FAKS: 90 (224) 2941903 myazici@uludag.edu.tr
18	Website:
19	Objective of the Course:	The purpose of this course is to help students apply basic principles of statics for rijid and deformable bodies and develop their engineering intuition for strength and deformation of engineering structures under external loadings. In addition, this course is intended to prepare students to apply design theory and approach that they learn for the mechanics of deformable bodies to complex systems that will be encountered in advanced design courses.
20	Contribution of the Course to Professional Development	This course provides the most basic principles for engineers who will work in the field of structural mechanics and material strength.

Learning Outcomes:

1	To be able to calculate stress and strain for tensile, compression, shear, torsion, bending and combined strength cases.;;
2	To be able to determine the mechanical properties and material constants of materials by using the engineering stress-strain curve obtained from the tensile test ;;
3	To be able to calculate the stress and strain caused by temperature changes.; ;
4	To be able to calculate the circumferential and axial stresses occurring in thin-walled tank exposed to internal pressure.; ;
5	To be able to realize the stress transformations for the plane stress state at any point;;
6	To be able to draw shear force and bending moment diagrams.; ;
7	To be able to determine the safe beam dimensions by calculating the normal and shear stresses caused by vertical loads on beams.; ;
8	To be able to solve torsion problems of solid and hollow shafts.; ;

22	Course Content:

Week	Theoretical	Practical
1	Definitions and content of the lesson
2	Internal force and stress concept, types of stress, axial loading, tensile test
3	Normal stress and strain
4	Shear stress and shear strain
5	Thermal stresses, general Hooke's Law, unit volume change, constitutive laws.
6	Thermal stresses, general form of Hooke's Law, constitutive law, Thin wall pressure vessels
7	Thin wall pressure vessels
8	Shear force and bending moment diagrams
9	Torsion of solid and hollow shafts
10	Bending, normal and shear stresses in beams
11	Pure Bending, dimensioning of beams affected by bending
12	Plane stress state and plane stress transformations at any point.
13	Plane stress state and plane stress transformations at any point.
14	Stresses in combined strength cases.

23	Textbooks, References and/or Other Materials:	I. H. Shames, “Introduction To Solid Mechanics”,Second Edition, Prentice-Hall International, Inc. E.P. Popov, ”Mechanics of Materials”, Second Edition, Prentice/Hall International Inc. E. J. Hearn, “Mechanics of Materials”, 2nd Edition, In Two Volumes, Volume I, Pergamon Press.
24	Assesment

TERM LEARNING ACTIVITIES	NUMBER	PERCENT
Midterm Exam	1	40
Quiz	0	0
Homeworks, Performances	0	0
Final Exam	1	60
Total	2	100
Contribution of Term (Year) Learning Activities to Success Grade		40
Contribution of Final Exam to Success Grade		60
Total		100
Measurement and Evaluation Techniques Used in the Course	Midterm, final exam
Information	Relative evaluation is carried out.

ECTS / WORK LOAD TABLE

CONTRIBUTION OF LEARNING OUTCOMES TO PROGRAMME QUALIFICATIONS

LO: Learning Objectives

PQ: Program Qualifications

Contribution Level:

1 Very Low

2 Low

3 Medium

4 High

5 Very High