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Course Information
Course Unit Code : 01MAK5107
Type of Course Unit : Optional
Level of Course Unit : Second Cycle
Year of Study : 1
Semester : 1.Semester
Number of ECTS Credits Allocated : 6,00
Name of Lecturer(s) : ---
Course Assistants : ---
Learning Outcomes of The Course Unit : 1) an ability to use knowledge of mathematics, science and engineering
2) an ability to design and conduct experiments as well as to analyze and interpret data
3) an ability to function on multidisciplinary teams
4) an ability to identify, formulate and solve engineering problems
5) an understanding of professional and ethical responsibility
6) an ability to communicate effectively
7) an ability to use the techniques and modern engineering tools necessary for engineering practice.
Mode of Delivery : Face-To-Face
Prerequisities and Co-requisities Courses : Unavailable
Recommended Optional Programme Components : Unavailable
Course Contents : This course is concerned with the fluid motion with friction, boundary layer theory, derivation of the equations of motion of a compressible viscous fluid, very slow flow motion, and thermal boundary layers in laminar flow.
Languages of Instruction : Turkish
Course Goals : This course will be helping to our students in engineering heat and fluid problems.
Course Aims : Our graduates will be successful in careers that deal with the design, simulation and analysis of engineering problems, experimentation and testing, manufacturing, and research.
WorkPlacement   Not Available
Recommended or Required Reading
Textbook :
Additional Resources : 1. G. K. Batchelor, ?A First Cours in Fluid Dynamics? 2. B. Thwaaaites (ed.), ?Incompressible Aerodynamics? 3. Hunter Rouse (ed.), ?Advanced Mechanics of Fluids? 4. R. L. Panton, ?Incompressible Flow? 5. L. M. Milne-Thompson, ?Theoretical Hydrodynamics? 6. Horace Lamb, ?Hydrodynamics? 7. W. Prager, ?Introduction to Mechanics of Continua? 8. L. D. Landau and E. M. Lipshitz, ?Fluid Mechanics? 9. N. E. Kochin, I. A. Kibel, and N. V. Roze, ?Theoritical Hydrodynamics? 10. D.J. Tritton, ?Physical Fluid Dynamics? 11. Schlichting, ?Boundary Layer Theory? 12. M. D. Van Dyke, ?An Album of Fluid Motion? 13. A. M. Kuethe and C-Y Chow, ?Foundations of Aerodynamics?
Material Sharing
Documents :
Assignments :
Exams :
Additional Material :
Planned Learning Activities and Teaching Methods
Lectures, Practical Courses, Presentation, Seminar, Project, Laboratory Applications (if necessary)
ECTS / Table Of Workload (Number of ECTS credits allocated)
Student workload surveys utilized to determine ECTS credits.
Activity :
Number Duration Total  
Course Duration (Excluding Exam Week) :
13 3 39  
Time Of Studying Out Of Class :
13 5 65  
Homeworks :
10 5 50  
Presentation :
5 1 5  
Project :
0 0 0  
Lab Study :
0 0 0  
Field Study :
0 0 0  
Visas :
1 10 10  
Finals :
1 10 10  
Workload Hour (30) :
Total Work Charge / Hour :
Course's ECTS Credit :
Assessment Methods and Criteria
Studies During Halfterm :
Number Co-Effient
Visa :
1 70
Quiz :
12 10
Homework :
5 15
Attendance :
0 5
Application :
0 0
Lab :
0 0
Project :
0 0
Workshop :
0 0
Seminary :
0 0
Field study :
0 0
The ratio of the term to success :
The ratio of final to success :
Weekly Detailed Course Content
Week Topics  
1 Fluid Motion with Friction: A- Real and Perfect Fluids B- Viscosity C- Compressibility
2 Fluid Motion with Friction: D- The Hagen-Poiseuille Equations of Flow Through a Pipe E- Principle of Similarity: The Reynolds and Mach Numbers F- Comparison Between The Theory of Perfect Fluids and Experiment
3 Boundary Layer Theory: A- The Boundary Layer Concept B- Separation and Vortex Formulation C- Turbulent Flow in a Pioe and in a Boundary Layer
4 Boundary Layer Theory: D- Turbulent Flow in a Pipe and in a Boundary Layer
5 Derivation of The Equations of Motion of a Compressible Viscous Fluid: A- Fundamental Equations of Motion and Continuity Applied to Fluid Flow B- General Stress System in a Deformable Body
6 Derivation of The Equations of Motion of a Compressible Viscous Fluid: C- The rate at which a Fluid Element is Strained in Flow D- Relation Between Stress and Rate of Deformation
7 Derivation of The Equations of Motion of a Compressible Viscous Fluid: E- Stokes?s Hypothesis F- Bulk Viscocity and Thermodynamic Pressure G- The Navier-Stokes Equations
8 Mid-term exam
9 Very Slow Flow Motion: A- The Differential Equations for the very Slow Flow Motion B- Parallel Flow Past a Sphere
10 Very Slow Flow Motion: C- The Hydrodynamic Theory of Lubrication D- The Hele ? Shaw Flow
11 Thermal Boundary Layers in Laminar Flow A- Derivation of The Energy Equation B- Temperature increase through adiabatic compression: stagnation temperature
12 Thermal Boundary Layers in Laminar Flow C- Theory of Similarity in Heat Transfer D- Exact Solutions for the Problem of Temperature Distribution in a Viscous Flow 1- Couette Flow 2- Poiseuille Flow Through a Channel with Flat Walls
13 Thermal Boundary Layers in Laminar Flow E- Boundary Layer Simplifications F- General Properties of Thermal Boundary Layers 1- Forced and Natural Flows 2- Adiabatic Wall 3- Analogy between heat transfer and Skin Friction 4- Effect of Prandtl Number
14 Thermal Boundary Layers in Laminar Flow G- Thermal Boundary Layers in Forced Flow 1- Parallel Flow Past a Flat Plate at Zero Incidence 2- Additional Similar Solutions of the Equations for Thermal Boundary Layers 3- Thermal Boundary Layers on Isothermal Bodies of Arbitrary Shape 4- Thermal Boundary Layers on Walls with an Arbitrary Temperature Distribution 5- Thermal Boundary Layers on Rotationally Symmetric and rotating bodies 6- Measurements on Cylinders and Other Body Shapes 7- Effect of Free Stream Turbulence H- Thermal Boundary Layers in Natural Flow