| Course Unit Code | Course Unit Title | Type of Course Unit | Year of Study | Semester | Number of ECTS Credits | | MM142 | İleri Akışkanlar Mekaniği | Elective | 1 | 2 | 6 |
|
| Level of Course Unit |
| Second Cycle |
| Objectives of the Course |
| "1.To provide students with knowledge in the advanced level fluid mechanics and use this
knowledge in the solution of engineering problems of interest.
2. To prepare students to related graduate programs." |
| Name of Lecturer(s) |
|
| Learning Outcomes |
| 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 | "A sound understanding of the boundary layer theory and ability to solve boundary layer equations in
differential and integral forms." | | 4 | Ability to solve laminar plane jets and comment on physical aspects of the results. | | 5 | Ability to solve cylindrical jets and comment on physical aspects of the results. | | 6 | "A sound understanding of turbulent flows, modeling of turbulent and ability to solve turbulent
boundary layer flows." |
|
| Mode of Delivery |
| Normal Education |
| Prerequisites and co-requisities |
| None |
| Recommended Optional Programme Components |
| None |
| Course Contents |
| "Review of conservation equations. Viscous flows, analytical solutions of Newtonian viscous-flow
equations: Couette flow, Poiseuille flow, Stoke's first and second problems. Low-Reynolds number flows.
Similarity solutions. Laminar boundary layers. Blasius and Falkner-Skan solutions. Boundary layer
separation. Plane and axisymmetric (round) laminar jets. Compressible boundary layers. Turbulent flow.
Turbulent boundary layers. Plane and axisymmetric turbulent jets." |
| Weekly Detailed Course Contents |
|
| 1 | Concepts of Fluid Mechanics | | | | 2 | Review of conservation equations, Potential flows: concepts of vorticity and circulation | | | | 3 | Viscous flows. Exact solutions: Couette flow, Parallel plate, rotating cylinder problems | | | | 4 | Viscous flows. Exact solutions: Poiseuille flow, flow in circular and non-circular ducts. | | | | 5 | Viscous flows. Exact solutions: Stokes' first and second problems | | | | 6 | Low Reynolds number flows | | | | 7 | Laminar boundary layer theory. Blasius and Falkner-Skan solutions | | | | 8 | Mid-term exam | | | | 9 | Momentum Integral solutions. Separation of boundary layer | | | | 10 | Laminar plane jet | | | | 11 | Laminar cylindrical jet | | | | 12 | Compressible boundary layers | | | | 13 | Turbulent flow, modeling of turbulence- | | | | 14 | Turbulent boundary layers | | | | 15 | Turbulent plane and cylindrical jets | | |
|
| Recommended or Required Reading |
| Çengel, Y. A. ,Cimbala, J. M. (2015). Akışkanlar Mekaniği - Temeller ve Uygulamalar. Ankara; Palme Yayınevi.
White, F. M. ,Ayder, E. (2009). Akışkanlar Mekaniği.İstanbul; Literatür Yayınevi
Rabi Karaali; Ders Notları |
| Planned Learning Activities and Teaching Methods |
|
| Assessment Methods and Criteria | |
| Midterm Examination | 1 | 100 | | SUM | 100 | |
| Final Examination | 1 | 100 | | SUM | 100 | | Term (or Year) Learning Activities | 40 | | End Of Term (or Year) Learning Activities | 60 | | SUM | 100 |
| | Language of Instruction | | Turkish | | Work Placement(s) | | None |
|
| Workload Calculation |
|
| Midterm Examination | 1 | 1 | 1 |
| Final Examination | 1 | 2 | 2 |
| Attending Lectures | 14 | 3 | 42 |
| Practice | 1 | 12 | 12 |
| Project Preparation | 1 | 12 | 12 |
| Seminar | 1 | 6 | 6 |
| Self Study | 14 | 5 | 70 |
| Individual Study for Mid term Examination | 1 | 10 | 10 |
| Individual Study for Final Examination | 1 | 12 | 12 |
|
| Contribution of Learning Outcomes to Programme Outcomes |
|
| * Contribution Level : 1 Very low 2 Low 3 Medium 4 High 5 Very High |
 |
| |