|
|
|
|
|
|||
 |
 |
 |
 |
 |
 |
 |
| class | date | subjects | reading | cwr | prob | due | |
| 01 M | Mar 04 | No Class!!! | |||||
| 02 T | 05 | No Class!!! | |||||
| 03 R | 07 | Overview; kinematic fluid properties | 1.1-1.3.3 | C-03 | P-01 | ||
| 04 F | 08 | Kinematic, transport, thermodynamic fluid properties | 1.3.3-1.3.17 | C-04 | P-02 | P-01 | |
| 05 M | 11 | Boundary conditions | 1.4-1.4.9 | C-05 | |||
| 06 T | 12 | Conservation laws; conservation of mass | 2.1-2.3 | C-06 | |||
| 07 R | 14 | Conservation of momentum | 2.4-2.4.1 | C-07 | |||
| 08 F | 15 | Deformation law; pressure | 2.4.2-2.4.3 | C-08 | P-03 | P-02 | |
| 09 M | 18 | Navier-Stokes equations; incompressible flow | 2.4.4-2.4.5 | C-09 | |||
| 10 T | 19 | Conservation of energy | 2.5 | C-10 | |||
| 11 R | 21 | Conservation of Energy; incompressible flow | 2.5-2.5.1 | C-11 | |||
| 12 F | 22 | Summary of equations; boundary conditions; coordinate systems | 2.5.2-2.7.3 | C-12 | P-04 | P-03 | |
| 13 M | 25 | Mathematical character; dimensionless parameters | 2.8-2.9 | C-13 | |||
| 14 T | 26 | Non-dimensionalization; creeping, boundary layer flows | 2.9.1-2.9.2, 2.11.1-2.11.2 |
C-14 | |||
| 15 R | 28 | Control volume formulations | 2.13-2.13.3 | C-15 | |||
| 16 F | 29 | Simplifications; solutions; Coutte flat plate flow |
3.1-3.2.1 | C-16 | P-05 | P-04 | |
| 17 M | Apr 01 | Coutte concentric cylinder flow; stability | 3.2.2-3.2.4 | C-17 | |||
| 18 T | 02 | Hagen-Poiseuille pipe flow | 3.3-3.3.1 | C-18 | |||
| 19 R | 04 | Coutte-Poiseuille flat plate flow | 3.3.2 | C-19 | |||
| 20 F | 05 | Non-circularduct flow; hydraulic diameter | 3.3.3-3.3.5 | C-20 | P-06 | P-05 | |
| Break | |||||||
| 21 M | 08 | Fully developed thermal duct flow | 3.3.5-3.3.7 | C-21 | |||
| 22 T | 09 | Unsteady duct flow | 3.4-3.4.2 | C-22 | |||
| 23 R | 11 | Oscillating flow above an infinite plate | 3.5-3.5.1 | C-23 | |||
| 24 F | 12 | Unsteady flow between two infinte plates | 3.5.2 | C-24 | P-07 | P-06 | |
| 25 M | 15 | Uniform suction flow on a plane porous duct flow |
3.6-3.6.2 3.6.3 |
C-25 | |||
| 26 T | 16 | Wind driven flows; Ekman drift | 3.7-3.7.1 | C-26 | |||
| 27 R | 18 | Similarity solutions; stagnation flow | 3.8-3.8.1 | C-27 | |||
| 28 F | 19 | Low reynolds number flows; immersed sphere | 3.9-3.9.2 | C-28 | P-08 | P-07 | |
| 29 M | 22 | Lubrication theory | 3.9.7 | C-29 | |||
| 30 T | 23 | Laminar boundary-layers; flat plate integral analysis |
4.1-4.1.4 | C-30 | |||
| 31 R | 25 | Flat plate integral analysis | 4.1.5-4.1.7 | C-31 | |||
| 32 F | 26 | The laminar boundary-layer equations; separation | 4.2-4.2.2 | C-32 | P-09 | P-08 | |
| 33 M | 29 | The celebrated Blasius solution | 4.3-4.3.2 | C-33 | |||
| 34 T | 30 | Falkner-Skan wedge flow | 4.3.3 | C-34 | |||
| 35 R | May 02 | The plane laminar jet | 4.4.2 | C-35 | |||
| 36 F | 03 | The linearly retarded flow of Howarth | 4.5.1 | C-36 | P-10 | P-09 | |
| 37 M | 06 | Buffer day or turbulent flow | C-37 | ||||
| 38 T | 07 | Buffer day or turbulent flow | C-38 | ||||
| 39 R | 09 | Buffer day or turbulent flow | C-39 | ||||
| 40 F | 10 | Evaluations and Review | P-10 | ||||
| TOP | |||||||
|
Prof. Zac Chambers Last modified: Sun Mar 10 13:24:41 US Eastern Standard Time 2002 |