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Název:
Using finite volume method to simulate laser shock peening of 7050 Al alloy
Autoři: Isoz, Martin ; Gruber, Pavel ; Ježek, Ondřej ; Kubíčková, Lucie ; Gabriel, Dušan ; Kaufman, Jan ; Brajer, Jan
Typ dokumentu: Příspěvky z konference
Konference/Akce: Engineering mechanics 2024 /30./, Milovy (CZ), 20240514
Rok: 2024
Jazyk: eng
Abstrakt: Laser shock peening (LSP) is a modern alternative to standard peening processes such as shot peening. In general, peening is used to improve the strength and fatigue resistance of components by hardening their surface. In LSP, a laser-induced shockwave is used to harden the material to a depth of the order of 1 mm, that is, roughly twice as deep as can be achieved with shot peening. Frameworks for LSP simulation have been developed since the end of the 1990s and are exclusively based on the finite element method (FEM). The critical component of the framework is the dynamic simulation of the elastoplastic shockwave that subjects the component material to a strain rate of the order 10−7 s−1. In this contribution, we present a simulation framework for LSP based on the finite volume method (FVM) that allows for modeling the strain-rate hardening of the material. The framework is used to simulate the LSP of the 7050 aluminum alloy. Using a comparison\nof our FVM results with the FEM data available in the literature, we found that FVM can be applied to LSP simulation with the same success as the more traditional FEM.
Klíčová slova: finite volume method; laser shock peening; modeling; OpenFOAM; simulation
Číslo projektu: TM04000048
Poskytovatel projektu: GA TA ČR
Zdrojový dokument: Engineering Mechanics 2024, ISBN 978-80-214-6235-9, ISSN 1805-8248
Poznámka: Související webová stránka: https://www.engmech.cz/im/proceedings/show/2024
Instituce: Ústav termomechaniky AV ČR (web)
Informace o dostupnosti dokumentu: Dokument je dostupný v příslušném ústavu Akademie věd ČR.
Původní záznam: https://hdl.handle.net/11104/0361342
Trvalý odkaz NUŠL: http://www.nusl.cz/ntk/nusl-669183
Autoři: Isoz, Martin ; Gruber, Pavel ; Ježek, Ondřej ; Kubíčková, Lucie ; Gabriel, Dušan ; Kaufman, Jan ; Brajer, Jan
Typ dokumentu: Příspěvky z konference
Konference/Akce: Engineering mechanics 2024 /30./, Milovy (CZ), 20240514
Rok: 2024
Jazyk: eng
Abstrakt: Laser shock peening (LSP) is a modern alternative to standard peening processes such as shot peening. In general, peening is used to improve the strength and fatigue resistance of components by hardening their surface. In LSP, a laser-induced shockwave is used to harden the material to a depth of the order of 1 mm, that is, roughly twice as deep as can be achieved with shot peening. Frameworks for LSP simulation have been developed since the end of the 1990s and are exclusively based on the finite element method (FEM). The critical component of the framework is the dynamic simulation of the elastoplastic shockwave that subjects the component material to a strain rate of the order 10−7 s−1. In this contribution, we present a simulation framework for LSP based on the finite volume method (FVM) that allows for modeling the strain-rate hardening of the material. The framework is used to simulate the LSP of the 7050 aluminum alloy. Using a comparison\nof our FVM results with the FEM data available in the literature, we found that FVM can be applied to LSP simulation with the same success as the more traditional FEM.
Klíčová slova: finite volume method; laser shock peening; modeling; OpenFOAM; simulation
Číslo projektu: TM04000048
Poskytovatel projektu: GA TA ČR
Zdrojový dokument: Engineering Mechanics 2024, ISBN 978-80-214-6235-9, ISSN 1805-8248
Poznámka: Související webová stránka: https://www.engmech.cz/im/proceedings/show/2024
Instituce: Ústav termomechaniky AV ČR (web)
Informace o dostupnosti dokumentu: Dokument je dostupný v příslušném ústavu Akademie věd ČR.
Původní záznam: https://hdl.handle.net/11104/0361342
Trvalý odkaz NUŠL: http://www.nusl.cz/ntk/nusl-669183
Záznam vytvořen dne 2025-01-19, naposledy upraven 2025-01-19.