Supplementary animations "on the clustering of low-aspect-ratio oblate spheroids settling in ambient fluid"

doi:doi:10.35097/1550

Supplementary animations "on the clustering of low-aspect-ratio oblate spheroids settling in ambient fluid"

TechnicalRemarks: ANIMATIONS FROM "On the clustering of low-aspect-ratio oblate spheroids settling in ambient fluid"

Authors: Manuel Moriche, Daniel Hettmann, Manuel García-Villalba and Markus Uhlmann.

Many-particle cases

Flow configuration

The animations correspond to the cases G111 and G152 described in table 1 from the original article. In these cases a set of many particles settle under gravity in a triply periodic configuration. The particles considered are oblate spheroids of aspect ratio 1.5 and the number of them is such that the solid volume fraction is 0.5%, which corresponds to the dilute regime. The cases differ from each other in the Galileo number: G=sqrt((rhop/rhof-1)*g*D**3)/nu=110.56 and 152.02 for cases G111 and G152, respectively. The size of computational domain is approximately [55x55x220]D**3, where D is the diameter of a sphere with the same volume as the spheroids and the resolution used (D/dx) is approximately 21.

The time is indicated in the videos is expressed in D/Ug units, where Ug=sqrt((rhop/rhof-1)*abs(g)*D) is a gravitationally scaled velocity.

Content

For each case there are different videos of the initial or converged state, or different representations of the flow/particles.

The case, part of the video and representation is contained in the name of each video: 1. Case: - G111: Galileo 110.56. - G152: Galileo 152.02. 2. Time interval of the simulation: - INITIAL: First simulated time, including the time before releasing the particles (t<0). - CONVERGED: Statistically stationary part of the simulation. 3. Point of view: bottom, iso, side and side_zoomed. 4. Representation. In every video particles are always represented in pink and wakes with transparency isocontours of Q criterion. Additionally, isocontours of filtered vertical velocity are represented in two ways: - low_speed: The value to define the isocontour is similar to that of the mixture. In this representation the regions in which particles are located in clustering/non-clustering regions are easily identified. Dark blue face points to non-clustering, slow regions and light blue face points to clustering, fast regions. - high_speed: The value to define isocontour is approximately 50% larger than the average velocity of the mixture. Therefore, the isocontours (in yellow) indicate regions of where the downward velocity is greatly enhanced. - only_wakes: No flow velocity is represented. Only side zoomed view is available for this representation.

Drafting-kissing-tumbling

For illustration purposes one animation is included (DKT_animation.mp4) of the drafting-kissing-tumbling simulations. The simulations have been performed for Galileo 110.56 with density ratio 1.5. The size of the computational domain measures [10.66 x 10.66 x 21.33] D**3. Four configurations are considered:

Free-to-rotate spheres (angular motion enabled).
Rotationally-locked spheres (angular motion suppressed).
Free-to-rotate spheroids of aspect ratio 1.5 (angular motion enabled).
Rotationally-locked spheroids of aspect ratio 1.5 (angular motion suppressed).

In the animation the four configurations are shown for a single initial condition, namely the relative position of the trailing particle with respect to the leading particle is [0.625, 7.5] D. The particles are represented in green with a mesh that helps to visualize the rotation and contours of vertical velocity are shown in grey scale.

References:

Manuel Moriche, Daniel Hettmann, Manuel García-Villalba and Markus Uhlmann, "On the clustering of low-aspect-ratio oblate spheroids settling in ambient fluid", accepted in J. Fluid Mech.

History:

04.10.2022 Creation and data added 06.02.2023 DKT animation added

Contact

Manuel Moriche Markus Uhlmann

BibTex:

@dataset{Moriche_Manuel_and_Hettmann_Daniel_and_García-Villalba_Manuel_and_Uhlmann_Markus_2023,
    abstract = {TechnicalRemarks: ANIMATIONS FROM _"On the clustering of low-aspect-ratio oblate spheroids settling in ambient fluid"_

Authors: Manuel Moriche, Daniel Hettmann, Manuel García-Villalba and Markus Uhlmann.

# Many-particle cases

## Flow configuration

The animations correspond to the cases G111 and G152 described in table 1 from the
original article. In these cases a set of many particles settle under gravity in a
triply periodic configuration. The particles considered are oblate spheroids of
aspect ratio 1.5 and the number of them is such that the solid volume fraction is 0.5%,
which corresponds to the dilute regime. The cases differ from each other in the Galileo
number: `G=sqrt((rhop/rhof-1)*g*D**3)/nu=110.56` and 152.02 for cases G111 and G152,
respectively. The size of computational domain is approximately `[55x55x220]D**3`,
where D is the diameter of a sphere with the same volume as the spheroids and the
resolution used (`D/dx`) is approximately 21.

The time is indicated in the videos is expressed in `D/Ug` units, where
`Ug=sqrt((rhop/rhof-1)*abs(g)*D)` is a gravitationally scaled velocity.

## Content

For each case there are different videos of the initial or converged state, or different
representations of the flow/particles.

The case, part of the video and representation is contained in the name of each video:
1. Case:
 - `G111`: Galileo 110.56.
 - `G152`: Galileo 152.02.
2. Time interval of the simulation:
 - `INITIAL`: First simulated time, including the time before releasing the particles (t<0).
 - `CONVERGED`: Statistically stationary part of the simulation.
3. Point of view: `bottom`, `iso`, `side` and `side_zoomed`.
4. Representation. In every video particles are always represented in pink and wakes with
   transparency isocontours of Q criterion. Additionally, isocontours of filtered vertical
   velocity are represented in two ways:
 - `low_speed`: The value to define the isocontour is similar to that of the mixture. In this
   representation the regions in which particles are located in clustering/non-clustering
   regions are easily identified. Dark blue face points to non-clustering, slow regions and
   light blue face points to clustering, fast regions.
 - `high_speed`: The value to define isocontour is approximately 50% larger than the average
   velocity of the mixture. Therefore, the isocontours (in yellow) indicate regions of
   where the downward velocity is greatly enhanced.
 - `only_wakes`: No flow velocity is represented. Only side zoomed view is available for
   this representation.

# Drafting-kissing-tumbling

For illustration purposes one animation is included (`DKT_animation.mp4`) of the 
drafting-kissing-tumbling simulations. The simulations have been performed 
for Galileo 110.56 with density ratio 1.5. The size of the computational domain 
measures `[10.66 x 10.66 x 21.33] D**3`. Four configurations are considered:

- Free-to-rotate spheres (angular motion enabled).
 - Rotationally-locked spheres (angular motion suppressed).
 - Free-to-rotate spheroids of aspect ratio 1.5 (angular motion enabled).
 - Rotationally-locked spheroids of aspect ratio 1.5 (angular motion suppressed).

In the animation the four configurations are shown for a single initial condition, namely
the relative position of the trailing particle with respect to the leading particle is  `[0.625, 7.5] D`.
The particles are represented in green with a mesh that helps to visualize the rotation and
contours of vertical velocity are shown in grey scale.

# References:

Manuel Moriche, Daniel Hettmann, Manuel García-Villalba and Markus Uhlmann,
_"On the clustering of low-aspect-ratio oblate spheroids settling in ambient fluid"_,
accepted in J. Fluid Mech.

# History:

__04.10.2022__ Creation and data added
__06.02.2023__ DKT animation added
# Contact

[Manuel Moriche](mailto:manuel.guerrero@kit.edu)
[Markus Uhlmann](mailto:markus.uhlmann@kit.edu)},
    author = {Moriche, Manuel and Hettmann, Daniel and García-Villalba, Manuel and Uhlmann, Markus},
    doi = {10.35097/1550},
    institution = {RADAR},
    title = {Supplementary animations "on the clustering of low-aspect-ratio oblate spheroids settling in ambient fluid"},
    url = {https://service.tib.eu/ldmservice/vdataset/rdr-doi-10-35097-1550},
    year = {2023}
}