Course Name
|
Turkish |
Akışkanlar Mekaniği
|
| English |
Fluid Mechanics |
Course Code
|
AKM 205 |
Credit |
Lecture
(hour/week) |
Recitation
(hour/week) |
Laboratory
(hour/week) |
| Semester |
4
|
4 |
5 |
2 |
- |
| Course Language |
Turkish |
| Course Coordinator |
Onur Tunçer
|
| Course Objectives |
1. To introduce the basic principles of fluid mechanics
2. To be able to define, formulate and simplify the equations of fluid flow and gain ability to use them for the solution of fluid flow problems
|
| Course Description |
Basic concepts and definitions. Fluid kinematics. Fluid statics. Manometers and pressure measurements. Hydrostatic forces on immersed bodies. Solid body translation and rotation. Equations of conservation of mass, momentum and energy for systems and control volumes Bernoulli equation and applications.. Navier-Stokes equations and its applications. Stream function and flow potential. Dimensional analysis and similarity. Viscous Flow in pipes and ducts. Laminar and turbulent boundary layers. Major and minor losses in pipes. Flow over immersed bodies. Boundary layer equations. Compressible flow. Fluid Machinery. Water hammer.
|
| Course Outcomes |
1.Have a knowledge of fluid concept, and similarities and differences between fluids and gases, be able to solve problems involving viscosity, surface tension, water vapor. [a3,c1,d2,e2,h1]
2.Be able to calculate hydrostatic forces, moments and point of action on submerged surfaces. [a3,c1,e3,h2]
3.Be able to classify flows as uniform/nonuniform, steady/unsteady, compressible/incompressible, laminar/turbulent, 1D/2D/3D. [e2,c1,g2,h1]
4.Be able to calculate mass flow rate, volumetric flow rate and mean velocity in a flow. [a3,b2,c2,e2,h2]
5.Learn pressure, velocity and mass flow rate measurement techniques. [a2,b3,f1,h1]
6.Be able to use control volume concept and Reynolds transport theorem to calculate fluid forces and moments acting on static or moving vanes, nozzles, bends, rotating systems. [a3,b1,c3,e3,f1,h2,i2,j2,k2]
7.Be able to apply dimensional analysis, similarity and modeling laws to fluid flow problems. [a3,b3,c3,d2,e3,f1,g2,h1,j1,k2]
8.Be able make calculations and use moody diagram to determine the local losses and resistance to flow in pipe systems [a3,b1,c1,e2,f1,g1,h2,i1,j1,k2]
9.Have a knowledge of lift and drag concepts over immersed bodies and their simple calculations. [a3,b2,c1,e2,f1,g1,h2,i1,j1,k2]
10.Have a knowledge of properties of compressible flow. [a2,b1,e1,i1,k2]
11.Have a knowledge of water hammer. [a1,e1]
12.Have a knowledge of pump and turbine characteristics; ability to choose the right pump or turbine for a given flow system. [a1,b1,c1,d1,e1,f1,h1,k2] |
| Pre-requisite(s) |
MAT102/ MAT102E or MAT104/ MAT104E |
| Required Facilities |
Computer usage might be necessary for some homeworks |
| Other |
|
| Textbook |
1.F. M. White, “Fluid Mechanics”, 5th Edition, McGraw Hill, 2005
2.B.R. Munson, D.F. Young and T. H. Okiishi, “Fundamentals of Fluid Mechanics”, 5th Edition, J. Wiley and Sons, NewYork, 2006. |
| Other References |
3.F. M. White, “Fluid Mechanics”, 4th Edition, McGraw Hill, 1999, Türkçe çevirisi, Kadir Kırkköprü, Erkan Ayder, Literatur Kitabevi, 2004
4.R.W. Fox, A.T. McDonald, “Introduction to Fluid Mechanics”, 4th Edition (SI)
5.V.L. Streeter, E.B. Wylie, “Fluid Mechanics”, Mc Graw Hill, 1983.
6.J.H. Shames, “Mechanics of Fluids”, Mc Graw Hill, 1992.
7.E.B. Wylie, “Fluid Mechanics”, Mac Graw Hill, 1983
8.Çengel, Y., Cimbala, C, “Fluid Mechanics”, 1st Edition, Mac Graw Hill, 2007, Türkçe Çevirisi, Ed. Tahsin Engin, Güven Kitabevi, 2008 |
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