{alias:nozzle}
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Author: Rajesh Bhaskaran, Cornell University
{color:#cc0000}{*}Problem Specification{*}{color}
[1. Pre-Analysis & Start-up|FLUENT - Compressible Flow in a Nozzle- Step 1]
[2. Geometry|FLUENT - Compressible Flow in a Nozzle- Step 2]
[3. Mesh|FLUENT - Compressible Flow in a Nozzle- Step 3]
[4. Setup (Physics)|FLUENT - Compressible Flow in a Nozzle- Step 4 *New]
[5. Solution|FLUENT - Compressible Flow in a Nozzle- Step 5 *New]
[6. Results|FLUENT - Compressible Flow in a Nozzle- Step 6 *New]
[7. Verification & Validation|FLUENT - Compressible Flow in a Nozzle- Step 7]
[Problem 1|FLUENT - Compressible Flow in a Nozzle- Problem 1]
[Problem 2|FLUENT - Compressible Flow in a Nozzle- Problem 2]
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h2. Problem Specification
!nozzle2.jpg!
Consider air flowing at high-speed through a convergent-divergent nozzle having a circular cross-sectional area, _A_, that varies with axial distance from the throat, _x_, according to the formula
A = 0.1 + x{^}2^; \-0.5 < x < 0.5
where _A_ is in square meters and _x_ is in meters. The stagnation pressure _p{_}{_}{~}o{~}_ at the inlet is 101,325 Pa. The stagnation temperature _T{_}{_}{~}o{~}_ at the inlet is 300 K. The static pressure _p_ at the exit is 3,738.9 Pa. We will calculate the Mach number, pressure and temperature distribution in the nozzle using FLUENT and compare the solution to quasi-1D nozzle flow results. The Reynolds number for this high-speed flow is large. So we expect viscous effects to be confined to a small region close to the wall. So it is reasonable to model the flow as inviscid.
Go to [Step 1: Pre-Analysis & Start-up|FLUENT - Compressible Flow in a Nozzle- Step 1]
[See and rate the complete Learning Module|FLUENTFluent - Compressible Flow in a Nozzle-Full]
[Go to all FLUENT Learning Modules|FLUENT Learning Modules] | 
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