Samenvatting
In this article, we study the effect of small-cut elements on the critical time-step size in an immersogeometric explicit dynamics context. We analyze different formulations for second-order (membrane) and fourth-order (shell-type) equations, and derive scaling relations between the critical time-step size and the cut-element size for various types of cuts. In particular, we focus on different approaches for the weak imposition of Dirichlet conditions: by penalty enforcement and with Nitsche's method. The conventional stability requirement for Nitsche's method necessitates either a cut-size dependent penalty parameter, or an additional ghost-penalty stabilization term. Our findings show that both techniques suffer from cut-size dependent critical time-step sizes, but the addition of a ghost-penalty term to the mass matrix serves to mitigate this issue. We confirm that this form of ‘mass-scaling’ does not adversely affect error and convergence characteristics for a transient membrane example, and has the potential to increase the critical time-step size by orders of magnitude. Finally, for a prototypical simulation of a Kirchhoff–Love shell, our stabilized Nitsche formulation reduces the solution error by well over an order of magnitude compared to a penalty formulation at equal time-step size.
| Originele taal-2 | Engels |
|---|---|
| Artikelnummer | 116074 |
| Aantal pagina's | 33 |
| Tijdschrift | Computer Methods in Applied Mechanics and Engineering |
| Volume | 412 |
| DOI's | |
| Status | Gepubliceerd - 1 jul. 2023 |
Financiering
S.K.F. Stoter gratefully acknowledges financial support through the Industrial Partnership Program Fundamental Fluid Dynamics Challenges in Inkjet Printing (FIP) , a joint research program of Canon Production Printing, Eindhoven University of Technology, University of Twente, and the Netherlands Organization for Scientific Research (NWO). C.V. Verhoosel and S.C. Divi acknowledge the partial support of the European Union’s Horizon 2020 research and innovation programme under Grant Agreement No 101017578 (SIMCor). M. Larson and E.H. van Brummelen gratefully acknowledge the insightful discussions at the special session organized by Prof. Trond Kvamsdal at IGA 2022 in Banff. All simulations have been performed using the open source software package Nutils [63] . S.K.F. Stoter gratefully acknowledges financial support through the Industrial Partnership Program Fundamental Fluid Dynamics Challenges in Inkjet Printing (FIP), a joint research program of Canon Production Printing, Eindhoven University of Technology, University of Twente, and the Netherlands Organization for Scientific Research (NWO). C.V. Verhoosel and S.C. Divi acknowledge the partial support of the European Union's Horizon 2020 research and innovation programme under Grant Agreement No 101017578 (SIMCor). M. Larson and E.H. van Brummelen gratefully acknowledge the insightful discussions at the special session organized by Prof. Trond Kvamsdal at IGA 2022 in Banff. All simulations have been performed using the open source software package Nutils [63].
Vingerafdruk
Duik in de onderzoeksthema's van 'Critical time-step size analysis and mass scaling by ghost-penalty for immersogeometric explicit dynamics'. Samen vormen ze een unieke vingerafdruk.Pers/Media
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Reports Outline Applied Mechanics and Engineering Study Results from Eindhoven University of Technology (Critical Time-step Size Analysis and Mass Scaling By Ghost-penalty for Immersogeometric Explicit Dynamics)
Verhoosel, C. V., Divi, S. C. & Stoter, K. F. S.
7/07/23
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