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Course Unit Title | Course Unit Code | Type of Course Unit | Level of Course Unit | Year of Study | Semester | ECTS Credits |
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Fluid Mechanics II | MMK313 | Elective | Bachelor's degree | 3 | Fall | 5 |
Prof. Dr. Hasan KARABAY
1) Ability to simplify the conservation equations and obtain exact solutions to some simple viscous flow problems and comment on the physical aspects of the results.
2) Ability to formulate, solve and gain a sound understanding of the application areas of low-Reynolds number flows.
3) Ability to solve laminar plane and pipe flow and comment on physical aspects of the results.
4) A sound understanding of viscid and inviscid flows
Program Competencies | ||||||||||||||||||||
1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 | 17 | 18 | 19 | ||
Learning Outcomes | ||||||||||||||||||||
1 | Low | High | Low | Low | High | High | No relation | No relation | Middle | Middle | No relation | No relation | No relation | No relation | No relation | No relation | High | No relation | High | |
2 | Low | High | Low | Low | High | High | No relation | No relation | Middle | Middle | No relation | No relation | No relation | No relation | No relation | No relation | High | No relation | High | |
3 | Low | High | Low | Low | High | High | No relation | No relation | Middle | Middle | No relation | No relation | No relation | No relation | No relation | No relation | High | No relation | High | |
4 | Low | High | Low | Low | High | High | No relation | No relation | Middle | Middle | No relation | No relation | No relation | No relation | No relation | No relation | High | No relation | High |
Face to Face
None
Calculus I, II -Differential equations, Linear algebra, fluid mechanics I
Fluid Kinematics, visualization of fluid motion. The Reynolds transport theorem, differential analysis of fluid flow, Navier-Stokes equation, some basic analytical solutions of Newtonian viscous-flow equations, Couette flow, Poiseuille flow, low-Reynolds number flows. inviscid flow, Euler’s equations of motion, The Bernoulli equation, circulation, irrotational flow, velocity potential, some basic plane potential flows, superposition of basic plane potential flows
1) Lecture
2) Drill and Practice
3) Lab / Workshop
4) Problem Solving
5) Project Based Learning
Contribution of Semester Studies to Course Grade |
40% |
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Contribution of Final Examination to Course Grade |
60% |
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Total | 100% |
English
Not Required