Beautiful sims Martin. Wow, Its nice to see a full transition through mach. In future videos could you perhaps show velocity in units of Mach number? Mach number speaks volumes.
Interesting. Could you please share some details regarding the grid size, type of elements used and the total cell number? I 'm working on something similar and I would appreciate to have some references. Thanks
This VOF simulation requires an extremely fine grid and a relatively small time step in order to resolve the flow in detail without adaptive methods. In this case, an unstructured two-dimensional grid with almost 400000 cells (polygonal and prism-layer cells) was used. The average size of the cells in the core was 0.16 % of the characteristic length (diameter of the flow domain). Ten prism layers with a total thickness of 0.08 % in relation to the characteristic length were used on the wall. The size of the time step was 0.2ms. The VOF model was used without the optional sharpening factor. I hope this is helpful.
Thanks a lot taking the time to answer my question. Is is ineed helpful look at the video and also to understand the grid resolution. I've done something similar in 2D with around 500k cells and VOF, in StarCCM+. For me was interesting to see that by using the tria mesh the results seemed more realistic than by using poly mesh. Thanks again and good luck with your projects.
Grüße, Vielen Dank für das hilfreiche Video Es könnte eine große Hilfe und möglicherweise neues Potenzial sein Benutzer nur dann, wenn die englische Version angezeigt werden kann sowie !@@! Prost,
I wanted to express my sincere appreciation and gratitude for creating this video, as it has been incredibly helpful to me. However, in the video(at 22:14), you mentioned creating two additional parts under Geometry >Parts > Block and Cylinder." I can't understand why you created these two additional parts and how they impact the simulation outcomes. Could you please clarify this aspect for me? Thanks in advance.
Those two parts are mainly created to describe specific areas inside the cyclone separator. By using volumetric controls under ( automated mesh -> custom controls -> volumetric control) the user can specify different mesh settings for different areas. In the tutorial this is used to create a very dense mesh inside the cyclone separator to resolve the swirling motion properly.
Eine stehende Welle als Überlagerung einer links- und einer rechtslaufenden Welle setzt voraus, dass beide Laufrichtungen gleichberechtigt sind. Bei der ebenen Poiseuille-Strömung ist diese links-rechts Symmetrie nicht gegeben, da es im gewählten Bezugssystem, in dem die festen Ränder ruhen, eine mittlere Strömung von links nach rechts gibt. Für das von uns gewählte Modell wäre die Antwort also: Nein.
Die ebene Poiseuille-Strömung (Grundzustand) ist für Reynoldszahlen Re < 49.6 monoton stabil (Energiebetrachtung) und für Re > 5772 linear instabil. Der Übergang zur Turbulenz kann ab Re = 1000 erfolgen (Drazin & Reid, 1981).
Good day Martin, I'm doing a research paper on an external gear pump and I'm applying the same models as for the lobe blower as it is essentially the same as an external gear pump but instead of air I just changed it to incompressible liquid (oil). I've spend quiet some time in the star ccm+ tutorial files trying to find out why we use the k-epsilon turbulent model and not the k-omega model, from what I can read I assume it is because the k-omega is sensitive to the value of omega in the free stream? But this issue was addressed by the SST K-omega model, so I'm a bit clueless on why we utilize the K-epsilon model then, any advice or pointers that would help me understand why we use that model would kindly be appreciated. kind regards Niel Joubert
The settings in tutorials are typically due to educational reasons or due to simplicity. Of course one can use these settings as a starting point, but for better results one has to adjust the cfd-model. For a gear pump I recommend the k-omega-SST turbulence model, which combines the advantages of the k-epsilon and the k-omega model.
Thank you. In the meantime, try this YT-Video: ANSYS FLUENT TRAINING: Golf ball Aerodynamics, CFD Simulation by ANSYS Fluent (ru-vid.com/video/%D0%B2%D0%B8%D0%B4%D0%B5%D0%BE-ZZk32wQ7-GE.html)
Vielen Dank für das hilfreiche Video. Nachdem mein Studium schon etwas länger her ist, konnte ich meine Kenntnisse zur CFD-Simulation durch dein Video wieder schnell auffrischen :)
For Details, please see the STAR-CCM+ Documentation: "Porous Resistance: Orthotropic Media" Tutorial. This tutorial solves the same problem as the "Porous Resistance: Isotropic Media" Tutorial, except that the fluid in the porous region cannot flow in any direction other than the bulk flow (y-) direction. This type of orthotropic porosity is specified by assigning large values to the inertial and viscous resistance components in the cross-flow directions (x- and z- directions in this case). The values of the components in the y-direction are the same as in the "Porous Resistance: Isotropic Media" Tutorial. Space: Three-Dimensional Material: Gas Flow: Segregated Flow Equation of State: Constant Density Time: Steady Viscous Regime: Turbulent, Reynolds-Averaged Navier-Stokes Reynolds-Averaged Turbulence: K-Epsilon Turbulence K-Epsilon Turbulence Models: Standard K-Epsilon K-Epsilon High y+ Wall Treatment: High y+ Wall Treatment The Video shows a modification of the original STAR-CCM+ model.
Yes, it's a tutorial. For Details please see the "Porous Resistance: Orthotropic Media"-Tutorial from the STAR-CCM+ Documentation: "This tutorial solves the same problem as the Porous Resistance: Isotropic Media, except that the fluid in the porous region cannot flow in any direction other than the bulk flow (y-) direction. This type of orthotropic porosity is specified by assigning large values to the inertial and viscous resistance components in the cross-flow directions (x- and z- directions in this case)."
Man kann die Wasseroberfläche am unteren Scheitelpunkt durch die Reflektion trotzdem gut sehen. Gut wäre noch eine mathematische Erklärung zu der eingezeichneten Parabel in selben Video. Und vielleicht dazu separat noch eine CFD VOF Simulation mit unterschiedlichen Modellen wie implizit und explizit etc.
Wir werden ein zweites Experiment (mit Video) dazu durchführen. Geplant ist die Verwendung von Lebensmittelfarbe, um die Parabel besser sehen zu können. Wir vergleichen ferner die Messung mit der Theorie.