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/- 1. FENSAP-ICE: Graphical Environment
- 2. Introductory Tutorials to In-Flight Icing
- 2.1. In-Flight Icing Using FENSAP Within FENSAP-ICE
- 2.1.1. FENSAP Airflow on the NACA0012 Airfoil
- 2.1.2. DROP3D Droplet Impingement on the NACA0012
- 2.1.3. ICE3D Ice Accretion on the NACA0012
- 2.1.4. Postprocessing an Ice Accretion Solution Using CFD-Post Macro
- 2.1.5. Multishot Ice Accretion with Automatic Mesh Displacement
- 2.1.6. FENSAP Performance Degradation
- 2.1.7. ICE3D: Required Heat Flux on a NACA0012
- 2.2. In-Flight Icing Using Fluent Within FENSAP-ICE
- 2.3. In-Flight Icing Using CFX Within FENSAP-ICE
- 2.4. In-Flight Icing Using FENSAP Within Workbench
- 2.5. In-Flight Icing Using CFX Within Workbench
- 2.6. In-Flight Icing Using Fluent Within Workbench
- 3. FENSAP Advanced Tutorials
- 4. DROP3D Advanced Tutorials
- 4.1. Droplet Impingement on a Complete Aircraft
- 4.2. Splashing and Bouncing by Post-Processing on a NACA23012 Airfoil
- 4.3. Splashing and Bouncing by Post Processing with Distribution on a NACA23012 Airfoil
- 4.4. Particle Re-Injection on a 3D Fuselage of a Commercial Business Jet
- 4.5. Droplet Impingement on an Engine Intake
- 5. ICE3D Advanced Tutorial
- 6. FENSAP-ICE-Unsteady Advanced Tutorials
- 7. CHT3D Advanced Tutorials
- 7.1. Unsteady Heat Conduction with Phase Change
- 7.2. Piccolo Tube Operating in the Dry Air Regime
- 7.3. Piccolo Tube Operating in the Wet Air Regime (Anti-Icing)
- 7.3.1. External Water Droplets Calculation
- 7.3.2. Initial ICE3D Calculation
- 7.3.3. Conjugate Heat Transfer (Wet-Air Regime)
- 7.3.4. Conjugate Heat Transfer (Wet-Air Regime) with Surface Roughness
- 7.3.5. Ice Accretion After CHT
- 7.3.6. Ice Accretion After CHT with Roughness
- 7.3.7. Multishot Ice Accretion After CHT with Roughness
- 7.4. Piccolo Tube Anti-Icing in Wet Air Using Fluent
- 7.4.1. Initial External Flow Calculation
- 7.4.2. Initial Internal Flow Calculation
- 7.4.3. External Water Droplets Calculation
- 7.4.4. Initial ICE3D Calculation
- 7.4.5. Conjugate Heat Transfer (Wet-Air Regime)
- 7.4.6. Conjugate Heat Transfer (Wet-Air Regime) with Surface Roughness
- 7.4.7. Ice Accretion After CHT
- 7.4.8. Ice Accretion After CHT with Roughness
- 7.5. Piccolo Tube Anti-Icing in Wet Air Using CFX
- 7.5.1. Initial External Flow Calculation
- 7.5.2. Initial Internal Flow Calculation
- 7.5.3. External Water Droplets Calculation
- 7.5.4. Initial ICE3D Calculation
- 7.5.5. Conjugate Heat Transfer (Wet-Air Regime)
- 7.5.6. Conjugate Heat Transfer (Wet-Air Regime) With Surface Roughness
- 7.5.7. Ice Accretion After CHT
- 7.5.8. Ice Accretion After CHT With Roughness
- 7.6. Unsteady Electro-Thermal De-icing in Wet Air
- 7.7. Unsteady Electro-Thermal De-icing in Wet Air Using Fluent with FENSAP-ICE
- 7.8. Electro-Thermal Simulation of a Heating Element
- 7.9. Axisymmetric Nacelle Anti-Icing System Operating in the Wet Air Regime – Droplets & Crystals
- 8. FENSAP-ICE-TURBO Advanced Tutorials
- 8.1. FENSAP Airflow Through a Turbofan
- 8.2. CFX Airflow Through a Turbofan
- 8.3. Impingement, Icing and Shedding on Rotating and Stationary Blades
- 8.3.1. Droplet and Ice Crystal Impingement
- 8.3.2. Post-Processing of Turbomachinery Droplet and Ice Crystal Solutions with CFD-Post Turbo
- 8.3.3. Mixed Phase Icing
- 8.3.4. Post-Processing of Turbomachinery Icing Solutions with CFD-Post Turbo
- 8.3.5. Mixed Phase Icing - Constant Relative Humidity
- 8.3.6. Ice Shedding on Rotating Components
- 8.4. Particle Reinjection
- 8.5. Engine Nose Cone Anti-Icing in Wet Air
- 8.6. Engine Nose Cone Anti-Icing in Wet Air Using Fluent
- 9. Tutorials on Mesh Adaptation
- 10. Multishot Advanced Tutorials
- 10.1. Multishot Glaze Ice on a Swept Tail With Automatic Remeshing
- 10.2. Mixed Phase Ice with CFX Airflow Solver and Automatic Remeshing Using Fluent Meshing
- Index