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• Information on Degree Programmes COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
Fluid Mechanics II ME   352 6 3 3 5

 Prerequisites and co-requisites Recommended Optional Programme Components None

Language of Instruction English Course Level First Cycle Programmes (Bachelor's Degree)
Course Type
Course Coordinator Prof.Dr. Beşir ŞAHİN
Instructors
 Prof.Dr. HÜSEYİN AKILLI 1. Öğretim Grup:A Prof.Dr. BEŞİR ŞAHİN 1. Öğretim Grup:B Prof.Dr. HÜSEYİN AKILLI 2. Öğretim Grup:A Prof.Dr. BEŞİR ŞAHİN 2. Öğretim Grup:B

Assistants
Goals
To teach the basic principles and equations of fluid mechanics; To present numerious and diverse real-world engineering examples to give students a feel for how fluid mechanics is applied in engineering practice; To develop a comprehensive understanding of fluid mechanics by emphasizing the physics of flow, and by supplying related figures and visual documents to reinforce the flow physics.
Content
Dimensional Analysis and Modeling Dimensional Analysis and Modeling Flow in Pipes Flow in Pipes Approximate Solutions of the Navier-Stokes Equation Approximate Solutions of the Navier-Stokes Equation Mid-term Exam Flow over Bodies: Drag and Lift Flow over Bodies: Drag and Lift Compressible Flow Compressible Flow Open Channel flow Open Channel flow Turbomachinery Introduction to Computational Fluid Mechanics Final Exam

Learning Outcomes
1) Understanding homogeneity and dimension analysis of units of dimensions, units and equations and knowing how to use the method
2) To know the fully developed flow properties with the laminar and turbulent flow in the pipes and to determine the pump power by calculating the continuous and local losses in the pipes
3) Know the advantages and disadvantages of different speed and flow measurement techniques
4) Ability to derive differential equations for mass and momentum conservation
5) Analytically solve different geometric flow problems
6) Appreciate why approximations are necessary to solve many fluid flow problems, and know when and where such approximations are appropriate
7) To be able to calculate boundary layer thickness
8) Have an intutive understanding of the various physical phenomena such as drag, friction and pressure drag reduction, and lift
9) To be able to calculate the drag force associated with flow over common geometries
10) To be able understand the effects of flow regime on the drag coefficients associated with flow over cylinders and spheres, -To understand the fundemetals of flow over airfoils and calculate the drag and lift forces acting on airfoils
11) Understanding why a nozzle must have a diveging section to accelerate a gas to supersonic speeds
12) To be able to evaluate the results of compressibility in gas flow and understand the causes of shock formation
13) To be able to understand the difference between the flow in the open channels and the pressurized flow in the pipes
14) Idetify various types of pumps and turbines, and understand how they work
15) To perform basic vector analysis of the flow into and out of pumps and turbines, -To use specific speed for preliminary design and selection of pump and turbines

Course's Contribution To Program
NoProgram Learning OutcomesContribution
12345
1
Student become equipped with the basic knowledge of math, science and engineering
X
2
Students gain a command of basic concepts, theories and principles in mechanical engineering
X
3
Students are able to design and carry out experiments in the basic fields of mechanical engineering, and interpret the results and the data obtained from the experiments
X
4
Students become equipped with a variety of skills and knowledge regarding engineering techniques
X
5
Students are able to design a system, component or process in order to meet the needs of various engineering problems within technical, economic, environmental, manufacturability, and sustainability limits.
X
6
Students independently review and learn the applications in an enterprise, make a critical assessment of the problems faced with, formulate problems and propose solutions by selecting the proper technique
X
7
Students take initiative in identification, design, development and use of a product or production process.
X
8
Students become aware of the necessity of lifelong learning and continuously self-renew
X
9
Students use English effectively for technical or non-technical topics orally or in wirtten form.
X
10
Students become effective in using computer, computer-aided drafting, design, analysis, and presentation
X
11
Students have good communicatino skills with a tendency to work in teams, and are able to work effectively as a member of an interdisciplinary team
X
12
Students become aware of the technical and ethical responsibilities, as well as being inquisitive and innovative
X

Course Content
WeekTopicsStudy Materials _ocw_rs_drs_yontem
1 Dimensional Analysis and Modeling Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Homework
2 Dimensional Analysis and Modeling Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Problem Solving
Homework
3 Flow in pipes, differantıal flow analysis Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Homework
4 Flow in pipes, differantıal flow analysis Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Problem Solving
Homework
5 Approximate Solutions of the Navier-Stokes Equation Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Homework
6 Approximate Solutions of the Navier-Stokes Equation Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Homework
7 Mid-term Exam Exam, Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Testing
8 Mid-Term Exam Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Problem Solving
Homework
9 Flow over Bodies: Drag and Lift Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Homework
10 Compressible Flow Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Problem Solving
Homework
11 Compressible Flow Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Homework
12 Open Channel flow Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Problem Solving
Homework
13 Open Channel flow Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Homework
14 Turbomachinery Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture
Discussion
Drilland Practice
Problem Solving
Homework
15 Introduction to Computational Fluid Mechanics Lecture, Exercise, Question Answer, Discussion, Practice, Question Answer, Discussion, Homework, Sampling Procedure Oral Information Exploration Lecture  