Software Open Access
Schlegel, Fabian; Bilde, Kasper Gram; Draw, Mazen; Evdokimov, Ilya; Hänsch, Susann; Khan, Harris; Krull, Benjamin; Lehnigk, Ronald; Li, Jiadong; Lyu, Hongmei; Meller, Richard; Petelin, Gašper; Tekavčič, Matej
{ "revision": 36, "stats": { "volume": 1559708808.0, "unique_downloads": 75.0, "version_unique_downloads": 1791.0, "unique_views": 437.0, "downloads": 108.0, "version_unique_views": 8357.0, "version_views": 13186.0, "version_downloads": 3334.0, "version_volume": 53457677833.0, "views": 632.0 }, "metadata": { "license": { "id": "GPL-3.0-only" }, "keywords": [ "Multiphase Flow", "Numerical Simulations", "OpenFOAM", "CFD", "Finite volume method", "Baseline model", "Multi-field two-fluid model", "Eulerian-Eulerian model", "Momentum interpolation", "Partial elimination algorithm", "Free Surface" ], "access_right": "open", "notes": "This work was supported by the Helmholtz European Partnering Program in the project \"Crossing borders and scales (Crossing)\"", "doc_id": "1", "publication_date": "2022-03-14", "communities": [ { "id": "energy" }, { "id": "fwd" }, { "id": "hzdr" }, { "id": "openfoam" }, { "id": "rodare" } ], "resource_type": { "type": "software", "title": "Software" }, "description": "<p>The HZDR multiphase addon contains additional code for the open-source CFD software OpenFOAM, released by <a href=\"http://www.openfoam.org\">The OpenFOAM Foundation</a>. The developments are dedicated to the numerical simulation of multiphase flows, in particular to the multi-field two-fluid model (Euler-Euler method). Within the OpenFOAM library the <em>multiphaseEulerFoam</em> framework is used for this type of simulation. The addon contains a modified solver named <em>HZDRmultiphaseEulerFoam</em> with the full support of the HZDR baseline model set for polydisperse bubbly flows. In addition a solver dedicated to a hybrid modelling approach (dispersed and resolved interfaces, Meller, Schlegel and Lucas, 2021) named <em>cipsaMultiphaseEulerFoam</em> is provided with the addon. This solver has an interface to the <em>multiphaseEulerFoam</em> framework and utilizes all available interfacial models of it.</p>\n\n<p><strong>General enhancements</strong></p>\n\n<ul>\n\t<li>modified turbulent wall functions of Menter according to Rzehak and Kriebitzsch (2015)</li>\n\t<li>dynamic time step adjustment via PID controller</li>\n</ul>\n\n<p><strong>HZDRmultiphaseEulerFoam</strong></p>\n\n<ul>\n\t<li>bubble induced turbulence model of Ma et al. (2017)</li>\n\t<li>drag model of Ishii and Zuber (1979) without correction for swarm and/or viscous effects</li>\n\t<li>wall lubrication model of Hosokawa et al. (2002)</li>\n\t<li>additional breakup and coalescence models for class method according to Kusters (1991) and Adachi et al. (1994)</li>\n\t<li>degassing boundary condition (fvModel)</li>\n\t<li>lift force correlation of Hessenkemper et al. (2021)</li>\n\t<li>lift force correlation of Saffman (1965) as extended by Mei (1992).</li>\n\t<li>aspect ratio correlation of Ziegenhein and Lucas (2017)</li>\n\t<li>real pressure treatment via explicit turbulent normal stress according to Rzehak et al. (2021)</li>\n\t<li>GPU-based accelerated computation of coalescence and breakup frequencies for the models of Lehr et al. (2002) (Petelin et al., 2021)</li>\n\t<li>configuration files and tutorials for easy setup of baseline cases according to Hänsch et al. (2021)</li>\n</ul>\n\n<p><strong>cipsaMultiphaseEulerFoam</strong></p>\n\n<ul>\n\t<li>morphology adaptive modelling framework for predicting dispersed and resolved interfaces based on Eulerian multi-field two-fluid model</li>\n\t<li>compact momentum interpolation method according to Cubero et al. (2014), including virtual mass</li>\n\t<li>numerical drag according to Strubelj and Tiselj (2011) to describe resolved interfaces in a volume-of-fluid like manner</li>\n\t<li>n-phase partial elimination algorithm for momentum equations to resolve strong phase coupling (Meller, Schlegel and Lucas, 2021)</li>\n\t<li>free surface turbulence damping (Frederix et al., 2018) for k-ω SST - symmetric and asymmetric - according to Tekav\u010di\u010d et al. (2021)</li>\n\t<li>sub-grid scale modelling framework (Meller, Schlegel and Klein, 2021)\n\t<ul>\n\t\t<li>additional LES models for the unclosed convective sub-grid scale term</li>\n\t\t<li>closure models for sub-grid surface tension term</li>\n\t</ul>\n\t</li>\n\t<li>configuration files and tutorials for easy setup of hybrid cases</li>\n</ul>", "references": [ "Adachi, Y., Stuart, M. C., & Fokkink, R. (1994). Kinetics of turbulent coagulation studied by means of end-over-end rotation. Journal of colloid and interface science, 165(2), 310-317.", "Cubero, A., S\u00e1nchez-Insa, A., & Fueyo, N. (2014). A consistent momentum interpolation method for steady and unsteady multiphase flows. Computers & Chemical Engineering, 62, 96-107.", "Frederix, E. M. A., Mathur, A., Dovizio, D., Geurts, B. J., & Komen, E. M. J. (2018). Reynolds-averaged modeling of turbulence damping near a large-scale interface in two-phase flow. Nuclear Engineering and Design, 333, 122-130.", "H\u00e4nsch, S., Evdokimov, I., Schlegel, F., & Lucas, D. (2021). A workflow for the sustainable development of closure models for bubbly flows. Chemical Engineering Science, 116807.", "Hessenkemper, H., Ziegenhein, T., Rzehak, R., Lucas, D., & Tomiyama, A. (2021). Lift force coefficient of ellipsoidal single bubbles in water. International Journal of Multiphase Flow, 138, 103587.", "Hosokawa, S., Tomiyama, A., Misaki, S., & Hamada, T. (2002, January). Lateral migration of single bubbles due to the presence of wall. In Fluids Engineering Division Summer Meeting (Vol. 36150, pp. 855-860).", "Ishii, M., & Zuber, N. (1979). Drag coefficient and relative velocity in bubbly, droplet or particulate flows. AIChE Journal, 25(5), 843-855.", "Kusters, K. A. (1991). The influence of turbulence on aggregation of small particles in agitated vessels. Eindhoven University of Technology.", "Lehr, F., Millies, M., & Mewes, D. (2002). Bubble\u2010size distributions and flow fields in bubble columns. AIChE Journal, 48(11), 2426-2443.", "Ma, T., Santarelli, C., Ziegenhein, T., Lucas, D., & Fr\u00f6hlich, J. (2017). Direct numerical simulation\u2013based Reynolds-averaged closure for bubble-induced turbulence. Physical Review Fluids, 2(3), 034301.", "Mei, R. (1992). An approximate expression for the shear lift force on a spherical particle at finite reynolds number. International Journal of Multiphase Flow, 18(1), 145-147.", "Meller, R., Schlegel, F., & Lucas, D. (2021). Basic verification of a numerical framework applied to a morphology adaptive multifield two\u2010fluid model considering bubble motions. International Journal for Numerical Methods in Fluids, 93(3), 748-773.", "Meller, R., Schlegel, F., & Klein, M. (2021). Sub-grid Scale Modelling and a-Posteriori Tests with a Morphology Adaptive Multifield Two-Fluid Model Considering Rising Gas Bubbles. Flow, Turbulence and Combustion, 1-28.", "Petelin, G., Lehnigk, R., Kelling, J., Papa, G., & Schlegel, F. (2021). GPU-based Accelerated Computation of Coalescence and Breakup Frequencies for Polydisperse Bubbly Flows. 30th International Conference Nuclear Energy for New Europe (NENE2021), Bled, Slovenia.", "Rzehak, R., & Kriebitzsch, S. (2015). Multiphase CFD-simulation of bubbly pipe flow: A code comparison. International Journal of Multiphase Flow, 68, 135-152.", "Rzehak, R., Liao, Y., Meller, R., Schlegel, F., Lehnigk, R., & Lucas, D. (2021). Radial pressure forces in Euler-Euler simulations of turbulent bubbly pipe flows. Nuclear Engineering and Design, 374, 111079.", "Saffmann P. G. (1965). The lift on a small sphere in a slow shear flow. Journal of Fluid Mechanics, 22(2), 385-400.", "\u0160trubelj, L., & Tiselj, I. (2011). Two\u2010fluid model with interface sharpening. International Journal for Numerical Methods in Engineering, 85(5), 575-590.", "Tekav\u010di\u010d, M., Meller, R., & Schlegel, F. (2021). Validation of a morphology adaptive multi-field two-fluid model considering counter-current stratified flow with interfacial turbulence damping. Nuclear Engineering and Design, 379, 111223.", "Ziegenhein, T., & Lucas, D. (2017). Observations on bubble shapes in bubble columns under different flow conditions. Experimental Thermal and Fluid Science, 85, 248-256." ], "doi": "10.14278/rodare.1480", "related_identifiers": [ { "scheme": "url", "relation": "isIdenticalTo", "identifier": "https://www.hzdr.de/publications/Publ-32194" }, { "scheme": "url", "relation": "isReferencedBy", "identifier": "https://www.hzdr.de/publications/Publ-32356" }, { "scheme": "url", "relation": "isReferencedBy", "identifier": "https://www.hzdr.de/publications/Publ-32323" }, { "scheme": "url", "relation": "isReferencedBy", "identifier": "https://www.hzdr.de/publications/Publ-32161" }, { "scheme": "doi", "relation": "isVersionOf", "identifier": "10.14278/rodare.767" } ], "version": "3.1.0", "contributors": [ { "type": "Other", "affiliation": "Eidgen\u00f6ssische Technische Hochschule Z\u00fcrich, Swizerland", "name": "Couteau, Arthur" }, { "type": "Other", "affiliation": "Faculty of Engineering and Physical Sciences, University of Leeds, United Kingdom", "name": "Colombo, Marco" }, { "type": "Other", "affiliation": 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