Hydroelastic potential flow solver suited for nonlinear wave dynamics in ice-covered waters
The aim of this paper is to introduce a fully nonlinear numerical finite element solver for the simulation of nonlinear wave processes in the presence of a solid ice sheet. In this study, solid ice cover referred to the size of the ice sheet and denoted that the length of the ice sheet was many time...
| Published in: | Ocean Engineering |
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| Main Authors: | , , , , , , , , |
| Format: | Article in Journal/Newspaper |
| Language: | English |
| Published: |
2022
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| Subjects: | |
| Online Access: | http://hdl.handle.net/11420/13171 |
| _version_ | 1835015923084296192 |
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| author | Hartmann, Moritz Cornelius Nikolaus Onorato, Miguel De Vita, Francesco Clauss, Günther F. Ehlers, Sören von Bock und Polach, Rüdiger Ulrich Franz Schmitz, Lars Hoffmann, Norbert Klein, Marco |
| author_facet | Hartmann, Moritz Cornelius Nikolaus Onorato, Miguel De Vita, Francesco Clauss, Günther F. Ehlers, Sören von Bock und Polach, Rüdiger Ulrich Franz Schmitz, Lars Hoffmann, Norbert Klein, Marco |
| author_sort | Hartmann, Moritz Cornelius Nikolaus |
| collection | Unknown |
| container_start_page | 111756 |
| container_title | Ocean Engineering |
| container_volume | 259 |
| description | The aim of this paper is to introduce a fully nonlinear numerical finite element solver for the simulation of nonlinear wave processes in the presence of a solid ice sheet. In this study, solid ice cover referred to the size of the ice sheet and denoted that the length of the ice sheet was many times larger than the longest relevant wavelength. The complexity of the ice sheet characteristics was assumed to be homogeneous, isotropic and in the linear elastic plate regime so that the deformation process could be modeled by the Kirchhoff–Love plate ansatz. The method presented was verified and validated for different ice dimensions and wave scenarios. At the beginning, the implementation of the flexural rigidity to the free surface boundary condition was verified by comparing the analytical wave-ice dispersion relation to simulation results with small amplitude regular waves and varying ice dimensions. Afterwards, the general applicability was validated by means of wave-ice experiments. The experiments were performed in the ice tank at Hamburg Ship Model Basin HSVA comprising regular waves and transient wave groups. |
| format | Article in Journal/Newspaper |
| genre | Ice Sheet ice covered waters |
| genre_facet | Ice Sheet ice covered waters |
| id | fttuhamburg:oai:tore.tuhh.de:11420/13171 |
| institution | Open Polar |
| language | English |
| op_collection_id | fttuhamburg |
| op_relation | Ocean engineering 0029-8018 http://hdl.handle.net/11420/13171 |
| publishDate | 2022 |
| record_format | openpolar |
| spelling | fttuhamburg:oai:tore.tuhh.de:11420/13171 2025-06-15T14:29:30+00:00 Hydroelastic potential flow solver suited for nonlinear wave dynamics in ice-covered waters Hartmann, Moritz Cornelius Nikolaus Onorato, Miguel De Vita, Francesco Clauss, Günther F. Ehlers, Sören von Bock und Polach, Rüdiger Ulrich Franz Schmitz, Lars Hoffmann, Norbert Klein, Marco 2022-09-01 http://hdl.handle.net/11420/13171 en eng Ocean engineering 0029-8018 http://hdl.handle.net/11420/13171 Hydroelasticity Nonlinear wave dynamics Numerical wave tank Transient wave groups Wave-ice interaction Wave-ice model tests Journal Article Other 2022 fttuhamburg 2025-05-16T03:52:31Z The aim of this paper is to introduce a fully nonlinear numerical finite element solver for the simulation of nonlinear wave processes in the presence of a solid ice sheet. In this study, solid ice cover referred to the size of the ice sheet and denoted that the length of the ice sheet was many times larger than the longest relevant wavelength. The complexity of the ice sheet characteristics was assumed to be homogeneous, isotropic and in the linear elastic plate regime so that the deformation process could be modeled by the Kirchhoff–Love plate ansatz. The method presented was verified and validated for different ice dimensions and wave scenarios. At the beginning, the implementation of the flexural rigidity to the free surface boundary condition was verified by comparing the analytical wave-ice dispersion relation to simulation results with small amplitude regular waves and varying ice dimensions. Afterwards, the general applicability was validated by means of wave-ice experiments. The experiments were performed in the ice tank at Hamburg Ship Model Basin HSVA comprising regular waves and transient wave groups. Article in Journal/Newspaper Ice Sheet ice covered waters Unknown Ocean Engineering 259 111756 |
| spellingShingle | Hydroelasticity Nonlinear wave dynamics Numerical wave tank Transient wave groups Wave-ice interaction Wave-ice model tests Hartmann, Moritz Cornelius Nikolaus Onorato, Miguel De Vita, Francesco Clauss, Günther F. Ehlers, Sören von Bock und Polach, Rüdiger Ulrich Franz Schmitz, Lars Hoffmann, Norbert Klein, Marco Hydroelastic potential flow solver suited for nonlinear wave dynamics in ice-covered waters |
| title | Hydroelastic potential flow solver suited for nonlinear wave dynamics in ice-covered waters |
| title_full | Hydroelastic potential flow solver suited for nonlinear wave dynamics in ice-covered waters |
| title_fullStr | Hydroelastic potential flow solver suited for nonlinear wave dynamics in ice-covered waters |
| title_full_unstemmed | Hydroelastic potential flow solver suited for nonlinear wave dynamics in ice-covered waters |
| title_short | Hydroelastic potential flow solver suited for nonlinear wave dynamics in ice-covered waters |
| title_sort | hydroelastic potential flow solver suited for nonlinear wave dynamics in ice-covered waters |
| topic | Hydroelasticity Nonlinear wave dynamics Numerical wave tank Transient wave groups Wave-ice interaction Wave-ice model tests |
| topic_facet | Hydroelasticity Nonlinear wave dynamics Numerical wave tank Transient wave groups Wave-ice interaction Wave-ice model tests |
| url | http://hdl.handle.net/11420/13171 |