At the end of this course, the students; 1) Acquire knowledge on the basics of kinematics and kinetics of particles and rigid bodies making planar motion. 2) Formulate and solve problems related to kinematics of particles and rigid bodies making planar motion. 3) Draw free body diagrams and formulate and solve problems related to kinetics of particles and rigid bodies making planar motion by using force and acceleration, work and energy and impulse and momentum concepts.
MODE OF DELIVERY
Face to face
PRE-REQUISITES OF THE COURSE
No
RECOMMENDED OPTIONAL PROGRAMME COMPONENT
Statics, Mathematical Analysis I-II
COURSE DEFINITION
General principles. Kinematics of particles. Rectilinear motion. Curvilinear motion: analysis in normal and tangential coordinates, analysis in polar coordinates. Relative motion analysis of particles. Kinetics of a particle: force, mass and acceleration. Work and energy principles. Impact. Impulse and momentum. Planar kinematics of a rigid body. Relative motion analysis. Mass moment of inertia. Kinetics of rigid bodies: Force and acceleration, energy and work, impulse and momentum.
COURSE CONTENTS
WEEK
TOPICS
1st Week
1st Week Kinematics of particles
2nd Week
2nd Week Kinematics of particles
3rd Week
3rd Week Kinetics of particles: Force and Acceleration
4th Week
4th Week Kinetics of particles: Force and Acceleration
5th Week
5th Week Kinetics of particles: Work and Energy
6th Week
6th Week Kinetics of particles: Work and Energy
7th Week
7th Week Kinetics of particles: İmpulse and momentum
8th Week
8th Week MID-TERM EXAM
9th Week
9th Week Planar kinematics of rigid bodies
10th Week
10th Week Planar kinematics of rigid bodies
11th Week
11th Week Planar Kinetics of Rigid Bodies: Force and Acceleration
12th Week
12th Week Planar kinematics of rigid bodies: Force and acceleration
13th Week
13th Week Planar kinetics of rigid bodies: Work and energy
14th Week
14th Week Planar kinetics of rigid bodies: impulse and momentum
RECOMENDED OR REQUIRED READING
Text Book : 1- Hibbeler, R., (2017) Engineering Mechanics: Dynamics, 14?th SI Edition, Pearson Education Reference Book(s): 1- Ferdinand Beer, E., Russell Johnston, Jr., (2010) Vector Mechanics for Engineers: Dynamics, 9?th Edition, McGraw-Hill. 2- Hibbeler, R.C, (2016) Mühendislik Mekaniği, Dinamik, Literatür Yayıncılık .
PLANNED LEARNING ACTIVITIES AND TEACHING METHODS
Lecture,Presentation,Problem Solving
ASSESSMENT METHODS AND CRITERIA
Quantity
Percentage(%)
Mid-term
1
25
Assignment
10
10
Quiz
2
20
Attendance
1
5
Total(%)
60
Contribution of In-term Studies to Overall Grade(%)
60
Contribution of Final Examination to Overall Grade(%)
40
Total(%)
100
ECTS WORKLOAD
Activities
Number
Hours
Workload
Midterm exam
1
2
2
Preparation for Quiz
14
,5
7
Individual or group work
14
2,5
35
Preparation for Final exam
14
2
28
Course hours
14
4
56
Preparation for Midterm exam
7
2
14
Laboratory (including preparation)
Final exam
1
2
2
Homework
6
2
12
Quiz
4
,8
3,2
Total Workload
159,2
Total Workload / 30
5,3
ECTS Credits of the Course
5
LANGUAGE OF INSTRUCTION
English
WORK PLACEMENT(S)
No
KEY LEARNING OUTCOMES (KLO) / MATRIX OF LEARNING OUTCOMES (LO)