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{alias:flatplate}
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Author: Rajesh Bhaskaran, Cornell University
{color:#ff0000}{*}Problem Specification{*}{color}
[1. Pre-Analysis & Start-up|FLUENT - Flat Plate Boundary Layer Step 1]
[2. Geometry|FLUENT - Flat Plate Boundary Layer Step 2]
[3. Mesh|FLUENT - Flat Plate Boundary Layer Step 3]
[4. Setup (Physics)|FLUENT - Flat Plate Boundary Layer Step 4 *New]
[5. Solution|FLUENT - Flat Plate Boundary Layer Step 5 *New]
[6. Results|FLUENT - Flat Plate Boundary Layer Step 6 *New]
[7. Verification and Validation|FLUENT - Flat Plate Boundary Layer Step 7]
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h2. Problem Specification

Go to [Step 1: Pre-Analysis and Start-up|SIMULATION:FLUENT - Flat Plate Boundary Layer Step 1]\\
\\  !boundary layer.png!\\ 
Consider air flowing across a flat plate boundary layer with a length of 1m and a vertical air flow length of 0.5m (this is valued used in this simulation, another suitable value can be chosen by the user). The fluid is flowing in the x-direction with a velocity of 1 m/s and the air flow exhausts into the ambient atmosphere which is at 1 atm. Take density to be 1 kg/m^3 and viscosity to be 10 x 10 \^(-3). Solve the problem using Fluent. The Reynold's number based on the plate length is 10,000. Plot the center line velocity and velocity profile at the outlet. Validate your results.\\
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[Go to Step 1: Pre-Analysis and Start-up|SIMULATION:FLUENT - Flat Plate Boundary Layer Step 1]\\

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