This is the data presented in the corresponding article in tabulated form

The results on five cases are given. two test cases include a horizontally oscillating cylinder in a rest flow and horizontal sloshing in a rectangular tank. Three water impact cases are a free falling wedge entering water, the water entry of a free falling multihull and the water entry of a free falling bow-flare ship section with various roll angles.

Video 1. Bubbles entrapment due to oblique droplet impact. ReL=220, VG=25 m/s. The video is slowed down 500 times. Video 2. Entrapment of bubbles due to oblique impact of remnants of a liquid bag onto the base film in front of a disturbance wave. ReL=360, VG=30 m/s. The video is slowed down 1000 times. Video 3. Entrapment of a large bubble due to overturning of a fast ripple wave. ReL=520, VG=25 m/s. The video is slowed down 1000 times.

This spreadsheet shows the inputs and outputs of the multidimensional spray convergence study

This data set contains all the data to produce the results of "Tariq Shajahan, Thijs Schouten, Shravan K.R. Raaghav, Cees van Rhee, Geert Keetels, Wim-Paul Breugem, Characteristics of slurry transport regimes: Insights from experiments and interface-resolved Direct Numerical Simulations, International Journal of Multiphase Flow, 2024, 104831, ISSN 0301-9322, https://doi.org/10.1016/j.ijmultiphaseflow.2024.104831". The flow problem was studied using a combination of experiments and Interface resolved Direct Numerical Simulations. The pipe geometry is implemented in the rectangular domain using a volume penalization method and periodic boundary conditions are applied at the ends of the pipe. The DNS is carried out rectangular domain filled with a viscous fluid in which immersed non-colloidal spherical particles are subjected to a crossflow along the pipe. The two phases in the simulation (fluid and particulate) are treated independently and coupled through a no-slip boundary condition enforced on the surface of the particle. The solution to the fluid phase is computed on a fixed Eulerian mesh and the moving surface of the particle is represented using a Lagrangian mesh that translates with the particle. The simulation code is developed in house and written in FORTRAN90. MATLAB, PYTHON and PARAVIEW has been used to generate the figures presented in the article.The Experimental data used for comparison is also included in the dataset.

This data set contains all the data to produce the results of "Tariq Shajahan, Thijs Schouten, Shravan K.R. Raaghav, Cees van Rhee, Geert Keetels, Wim-Paul Breugem, Characteristics of slurry transport regimes: Insights from experiments and interface-resolved Direct Numerical Simulations, International Journal of Multiphase Flow, 2024, 104831, ISSN 0301-9322, https://doi.org/10.1016/j.ijmultiphaseflow.2024.104831". The flow problem was studied using a combination of experiments and Interface resolved Direct Numerical Simulations. The pipe geometry is implemented in the rectangular domain using a volume penalization method and periodic boundary conditions are applied at the ends of the pipe. The DNS is carried out rectangular domain filled with a viscous fluid in which immersed non-colloidal spherical particles are subjected to a crossflow along the pipe. The two phases in the simulation (fluid and particulate) are treated independently and coupled through a no-slip boundary condition enforced on the surface of the particle. The solution to the fluid phase is computed on a fixed Eulerian mesh and the moving surface of the particle is represented using a Lagrangian mesh that translates with the particle. The simulation code is developed in house and written in FORTRAN90. MATLAB, PYTHON and PARAVIEW has been used to generate the figures presented in the article.The Experimental data used for comparison is also included in the dataset.

Data: Code:Supplementary material: One video shows the underwater drone filming the bubble curtain. The second video shows an overview of the bubble curtain. The bubble curtain was 31 m wide and 10 m high with 2 mm holes drilled every 100mm. This research was carried out in the light of sound mitigation by bubble curtains. Both the hydrodynamic and acoustic properties of the bubble curtain were measured. The data was collected using an underwater drone with a camera and a stationary underwater camera.

Data: Code:Supplementary material: One video shows the underwater drone filming the bubble curtain. The second video shows an overview of the bubble curtain. The bubble curtain was 31 m wide and 10 m high with 2 mm holes drilled every 100mm. This research was carried out in the light of sound mitigation by bubble curtains. Both the hydrodynamic and acoustic properties of the bubble curtain were measured. The data was collected using an underwater drone with a camera and a stationary underwater camera.

CompressibePhaseChangeFoam

This dataset contains the compressible two-phase, one-fluid solver called compressiblePhaseChangeFoam, developed and maintained by the Institute for Combustion Technology in Stuttgart.

Versions

This dataset contains the full git repository of the compressiblePhaseChangeFoam solver with the complete development history, starting in 2018. For some publications, older versions of the software have been used. While the newest version should produce the same results, it might be necessary for older cases to checkout the corresponding code version with the Git hash. By providing the complete Git history, all versions can be checked out, and the development process can be recovered as well.

Build & Install Requirements

The solver is based on OpenFOAM v2012 and is tested for the following settings:

• Operating system: Ubuntu 22.04
• Compiler: gcc-9.5
• OpenFOAM version: v2012 (compiled with gcc-9.5)

Third Party Libraries

The presented solver uses a tabulated thermophysical properties library called tabularThermo. This library is independently developed by the same authors as the solver; however, it is not publicly available. To allow compilation and computation with this library, the tabularThermo git sub-module is included in the tar archive. The solver also includes some unit testing with the Catch2 framework, which is included as a single header library. The Catch2 library is published under the BSL-1.0 license.

Related Publications

A full list of related publications is given in the Meta Data tab.

• J. W. Gärtner, A. Kronenburg, A. Rees, J. Sender, M. Oschwald, and G. Lamanna, "Numerical and Experimental Analysis of Flashing Cryogenic Nitrogen", International Journal of Multiphase Flow, vol 130, 2020, doi: 10.1016/j.ijmultiphaseflow.2020.103360
• J. W. Gärtner, Y. Feng, A. Kronenburg, and O. T. Stein, "Numerical Investigation of Spray Collapse in GDI with OpenFOAM", Fluids, 6, 104, doi: 0.3390/fluids6030104
• J. W. Gärtner, A. Kronenburg, A. Rees, and M. Oschwald, "Investigating 3-D Effects on Flashing Cryogenic Jets wiht Highly Resolved LES", Flow, Turbulence and Combustion, 2023, doi: 10.1007/s10494-023-00485-4
• J. W. Gärtner and A. Kronenburg, "A Novel ELSA Model for Flash Evaporation", International Journal of Multiphase Flow, vol. 174, 2024, doi: 10.1016/j.ijmultiphaseflow.2024.104784

Python