Block Structured Amr Adaptive Mesh Refinement For Jet Atomization Case 1

Media Summary: Re=440, We=1270 Diameter 0.1mm refinement level 3-9 Blocked Tank length L=0.2m λ/L=1.0 wave height/L=0.13 refinement level 2-5 Blocked Re=740, We=3530 Diameter 0.1mm refinement level 3-9 Blocked

Block Structured Amr Adaptive Mesh Refinement For Jet Atomization Case 1 - Detailed Analysis & Overview

Re=440, We=1270 Diameter 0.1mm refinement level 3-9 Blocked Tank length L=0.2m λ/L=1.0 wave height/L=0.13 refinement level 2-5 Blocked Re=740, We=3530 Diameter 0.1mm refinement level 3-9 Blocked Diameter=500𝜇m, Re=3300, We=289 Blocked Tank length L=0.5m λ/L=1.0 wave height/L=0.13 refinement level 2-6 Blocked Recently, our research project "Pegasus" for swirl atomisation of molten metal was started. We have performed first simulations ...

Re = 837 Plate thickness H = 8.1×10-4 m Width-to-thickness ratio is Λ = 8 Dimensionless moment of inertia is I* = 0.29 Aluminum ... Capturing the Free Surface Accurately with In this tutorial, we will see how to implement Presented at the Argonne Training Program on Extreme-Scale Computing 2019. Slides for this presentation are available here: ... Re = 1147 Plate thickness H = 8.1×10-4 m Width-to-thickness ratio Λ = 14 Dimensionless moment of inertia I* = 0.16 Aluminum ...

Photo Gallery

Block-Structured AMR (adaptive mesh refinement) for jet atomization, case-1

Adaptive Mesh Refinement (AMR) in OpenFOAM: Consistent Interface Resolution for Atomization

Block-Structured AMR (adaptive mesh refinement) for breaking wave case-1

Block-Structured AMR (adaptive mesh refinement) for jet atomization, case-2

Block-Structured AMR (adaptive mesh refinement) for Jet impeling

Block-Structured AMR (adaptive mesh refinement) for breaking wave case-2 a

Swirl atomisation with OpenFOAM's interFoam: VOF approach with adaptive mesh refinement

Block-Structured AMR (adaptive mesh refinement) for FSI (fluid structure interaction) Case 2

Capturing the Free Surface Accurately with Adaptive Mesh Refinement (AMR)

Adaptive Mesh Refinement (AMR) | OpenFOAM

Simulation of a falling droplet using adaptive mesh refinement (a more accurate interface capturing)

AMReX: Building a Block-Structured AMR Application ǀ Ann Almgren and Donald Willcox, LBNL

View Detailed Profile

Block-Structured AMR (adaptive mesh refinement) for jet atomization, case-1

Block-Structured AMR (adaptive mesh refinement) for jet atomization, case-1

Re=440, We=1270 Diameter 0.1mm refinement level 3-9 Blocked

Adaptive Mesh Refinement (AMR) in OpenFOAM: Consistent Interface Resolution for Atomization

Adaptive Mesh Refinement (AMR) in OpenFOAM: Consistent Interface Resolution for Atomization

Adaptive Mesh Refinement

Block-Structured AMR (adaptive mesh refinement) for breaking wave case-1

Block-Structured AMR (adaptive mesh refinement) for breaking wave case-1

Tank length L=0.2m λ/L=1.0 wave height/L=0.13 refinement level 2-5 Blocked

Block-Structured AMR (adaptive mesh refinement) for jet atomization, case-2

Block-Structured AMR (adaptive mesh refinement) for jet atomization, case-2

Re=740, We=3530 Diameter 0.1mm refinement level 3-9 Blocked

Block-Structured AMR (adaptive mesh refinement) for Jet impeling

Block-Structured AMR (adaptive mesh refinement) for Jet impeling

Diameter=500𝜇m, Re=3300, We=289 Blocked

Block-Structured AMR (adaptive mesh refinement) for breaking wave case-2 a

Block-Structured AMR (adaptive mesh refinement) for breaking wave case-2 a

Tank length L=0.5m λ/L=1.0 wave height/L=0.13 refinement level 2-6 Blocked

Swirl atomisation with OpenFOAM's interFoam: VOF approach with adaptive mesh refinement

Swirl atomisation with OpenFOAM's interFoam: VOF approach with adaptive mesh refinement

Recently, our research project "Pegasus" for swirl atomisation of molten metal was started. We have performed first simulations ...

Block-Structured AMR (adaptive mesh refinement) for FSI (fluid structure interaction) Case 2

Block-Structured AMR (adaptive mesh refinement) for FSI (fluid structure interaction) Case 2

Re = 837 Plate thickness H = 8.1×10-4 m Width-to-thickness ratio is Λ = 8 Dimensionless moment of inertia is I* = 0.29 Aluminum ...

Capturing the Free Surface Accurately with Adaptive Mesh Refinement (AMR)

Capturing the Free Surface Accurately with Adaptive Mesh Refinement (AMR)

Capturing the Free Surface Accurately with

Adaptive Mesh Refinement (AMR) | OpenFOAM

Adaptive Mesh Refinement (AMR) | OpenFOAM

In this tutorial, we will see how to implement

Simulation of a falling droplet using adaptive mesh refinement (a more accurate interface capturing)

Simulation of a falling droplet using adaptive mesh refinement (a more accurate interface capturing)

Simulation of multiphase flow. In this

AMReX: Building a Block-Structured AMR Application ǀ Ann Almgren and Donald Willcox, LBNL

AMReX: Building a Block-Structured AMR Application ǀ Ann Almgren and Donald Willcox, LBNL

Presented at the Argonne Training Program on Extreme-Scale Computing 2019. Slides for this presentation are available here: ...

Parallel block structured adaptive mesh refinement (BAMR) for FSI (fluid structure interaction)

Parallel block structured adaptive mesh refinement (BAMR) for FSI (fluid structure interaction)

Re = 1147 Plate thickness H = 8.1×10-4 m Width-to-thickness ratio Λ = 14 Dimensionless moment of inertia I* = 0.16 Aluminum ...