Description

General equations of motion of viscous fluid. Exact solutions of the Navier Stokes equations. Flow at small Reynolds number. The laminar boundary layer theory. Non-steady boundary layers. Boundary layer control. Transition and turbulent boundary layers. Analysis of theoretical and experimental data. Case studies and design problems encountered in various fluid flows and related fields.

Program

M.Sc. In Mechanical Engineering

Objectives

Acquire good understanding and deep insight into the different types of fluid flows.rnDesign, analyze and solve any problem in the field of fluid flows and related topics.rn

Textbook

Data will be available soon!

Course Content

content serial	Description
1	Introduction.
2	General equations of motion of viscous fluid
3	Exact solutions of the Navier Stokes equations
4	Exact solutions of the Navier Stokes equations (Cont.)
5	Flow at small Reynolds number
6	The laminar boundary layer theory
7	The laminar boundary layer theory (Cont.) / 7th week evaluation.
8	Exact solutions of the boundary layer equations.
9	Exact solutions of the boundary layer equations (Cont.).
10	Non-steady boundary layers
11	Boundary layer control
12	Transition and turbulent boundary layers / 12th week evaluation
13	Turbulent boundary layer.
14	Turbulent boundary layer (Cont.).
15	Case studies and design problems encountered on\in various fluid flows and related fields
16	Final Examination

Markets and Career

Generation, transmission, distribution and utilization of electrical power for public and private sectors to secure both continuous and emergency demands.
Electrical power feeding for civil and military marine and aviation utilities.
Electrical works in construction engineering.

Degree Master
Code: ME 761
Credit hrs: 3
Prequisites: None

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Advanced Fluid Mechanics