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Application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal - polymer composites
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| Veröffentlicht in: | Procedia engineering 81(2014), Seite 1348 – 1353 |
|---|---|
| Personen und Körperschaften: | , , , |
| Titel: | Application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal - polymer composites/ Natalia Konchakova; Swantje Bargmann |
| Format: | E-Book-Kapitel |
| Sprache: | Englisch |
| veröffentlicht: |
2014
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| Gesamtaufnahme: |
: Procedia engineering, 81(2014), Seite 1348 – 1353
, volume:81 |
| Schlagwörter: | |
| Quelle: | Verbunddaten SWB Lizenzfreie Online-Ressourcen |
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| 520 | |a © 2014 The Authors. Published by Elsevier Ltd. The application of a gradient extended theory to the computation of the mechanical response of a single crystalline sub-micron gold, which is the part of nano-composites, is in the focus of the contribution. The research takes into account the dependence of the macroscopic behavior of a crystalline material on the size and morphology of the grains, the volume fraction of different phases, and the subgrain material modeling. A gradient hardening contribution is included into the crystal plasticity model in order to study the influence of the grain size on the response of single crystalline. It is assumed that the grain boundaries act as barriers to plastic deformation. The highly coupled system of equations is solved by applying a dual mixed finite element algorithm. Numerical results of the sub-micron gold crystal deformation under cyclic shear loading are presented. The gradient effect in the deformation field is discussed. | ||
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| contents | © 2014 The Authors. Published by Elsevier Ltd. The application of a gradient extended theory to the computation of the mechanical response of a single crystalline sub-micron gold, which is the part of nano-composites, is in the focus of the contribution. The research takes into account the dependence of the macroscopic behavior of a crystalline material on the size and morphology of the grains, the volume fraction of different phases, and the subgrain material modeling. A gradient hardening contribution is included into the crystal plasticity model in order to study the influence of the grain size on the response of single crystalline. It is assumed that the grain boundaries act as barriers to plastic deformation. The highly coupled system of equations is solved by applying a dual mixed finite element algorithm. Numerical results of the sub-micron gold crystal deformation under cyclic shear loading are presented. The gradient effect in the deformation field is discussed. |
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| spelling | Konchakova, Natalia VerfasserIn (DE-588)1172216193 (DE-627)1040987281 (DE-576)514423951 aut, Application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal - polymer composites Natalia Konchakova; Swantje Bargmann, 2014, Diagramme, Text txt rdacontent, Computermedien c rdamedia, Online-Ressource cr rdacarrier, Technische Universität Hamburg-Harburg, Institute of Continuum Mechanics and Material Mechanics, © 2014 The Authors. Published by Elsevier Ltd. The application of a gradient extended theory to the computation of the mechanical response of a single crystalline sub-micron gold, which is the part of nano-composites, is in the focus of the contribution. The research takes into account the dependence of the macroscopic behavior of a crystalline material on the size and morphology of the grains, the volume fraction of different phases, and the subgrain material modeling. A gradient hardening contribution is included into the crystal plasticity model in order to study the influence of the grain size on the response of single crystalline. It is assumed that the grain boundaries act as barriers to plastic deformation. The highly coupled system of equations is solved by applying a dual mixed finite element algorithm. Numerical results of the sub-micron gold crystal deformation under cyclic shear loading are presented. The gradient effect in the deformation field is discussed., Extended crystal plasticity DSpace, Finite elements DSpace, Gradient hardening DSpace, Size effect DSpace, Sub-micron gold DSpace, Bargmann, Swantje 1980- VerfasserIn (DE-588)136307426 (DE-627)579315576 (DE-576)300953763 aut, Technische Universität Hamburg-Harburg (DE-588)2067664-5 (DE-627)103632417 (DE-576)192125400 oth, Technische Universität Hamburg-Harburg Institute of Continuum Mechanics and Material Mechanics (DE-588)104784821X (DE-627)779307852 (DE-576)401665941 oth, Enthalten in Procedia engineering Amsterdam [u.a.] : Elsevier, 2009 81(2014), Seite 1348 – 1353 Online-Ressource (DE-627)607348992 (DE-600)2509658-8 (DE-576)310099773 1877-7058 nnns, volume:81 year:2014 pages:1348 – 1353, http://nbn-resolving.de/urn:nbn:de:gbv:830-882.050941 Resolving-System kostenfrei, https://doi.org/10.15480/882.2421 Resolving-System kostenfrei, http://hdl.handle.net/11420/3506 Resolving-System kostenfrei, https://doi.org/10.1016/j.proeng.2014.10.155 Verlag, https://doi.org/10.1016/j.proeng.2014.10.155 LFER, http://nbn-resolving.de/urn:nbn:de:gbv:830-882.050941 LFER, LFER 2019-12-05T00:00:00Z |
| spellingShingle | Konchakova, Natalia, Bargmann, Swantje, Application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal - polymer composites, © 2014 The Authors. Published by Elsevier Ltd. The application of a gradient extended theory to the computation of the mechanical response of a single crystalline sub-micron gold, which is the part of nano-composites, is in the focus of the contribution. The research takes into account the dependence of the macroscopic behavior of a crystalline material on the size and morphology of the grains, the volume fraction of different phases, and the subgrain material modeling. A gradient hardening contribution is included into the crystal plasticity model in order to study the influence of the grain size on the response of single crystalline. It is assumed that the grain boundaries act as barriers to plastic deformation. The highly coupled system of equations is solved by applying a dual mixed finite element algorithm. Numerical results of the sub-micron gold crystal deformation under cyclic shear loading are presented. The gradient effect in the deformation field is discussed., Extended crystal plasticity, Finite elements, Gradient hardening, Size effect, Sub-micron gold |
| title | Application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal - polymer composites |
| title_auth | Application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal - polymer composites |
| title_full | Application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal - polymer composites Natalia Konchakova; Swantje Bargmann |
| title_fullStr | Application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal - polymer composites Natalia Konchakova; Swantje Bargmann |
| title_full_unstemmed | Application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal - polymer composites Natalia Konchakova; Swantje Bargmann |
| title_in_hierarchy | Application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal - polymer composites / Natalia Konchakova; Swantje Bargmann, |
| title_short | Application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal - polymer composites |
| title_sort | application of a gradient crystal plasticity model to numerical analysis of metal part of nanoporous metal polymer composites |
| topic | Extended crystal plasticity, Finite elements, Gradient hardening, Size effect, Sub-micron gold |
| topic_facet | Extended crystal plasticity, Finite elements, Gradient hardening, Size effect, Sub-micron gold |
| url | http://nbn-resolving.de/urn:nbn:de:gbv:830-882.050941, https://doi.org/10.15480/882.2421, http://hdl.handle.net/11420/3506, https://doi.org/10.1016/j.proeng.2014.10.155 |
| urn | urn:nbn:de:gbv:830-882.050941 |