Experimental and Simulation Analysis of Effects of Laser Bending on Microstructures Applied to Advanced Metallic Alloys

Experimental and Simulation Analysis of Effects of Laser Bending on Microstructures Applied to Advanced Metallic Alloys

The aim of this work is the analysis of laser beam forming (LBF) in the bending of two relevant materials used in the transportation industry—interstitial-free (IF) steel and AA6013 high-strength aluminum alloy. Our experiments and numerical simulations consider two different operating scenarios ach...

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Main Authors: Esteban Ramos-Moore, Joaquín Hoffmann, Rafael H. M. Siqueira, Sheila Medeiros de Carvalho, Milton S. Fernandes de Lima, Diego J. Celentano
Format: Article
Language:English
Published: MDPI AG 2021-02-01
Series:Metals
Subjects:
laser beam forming
microstructure
interstitial-free steels
aluminum alloys
modeling and numerical simulation
Online Access:https://www.mdpi.com/2075-4701/11/2/362
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spelling doaj-fa06b20d29954d6698c7b31f0209bb8f2021-02-22T00:02:31ZengMDPI AGMetals2075-47012021-02-011136236210.3390/met11020362Experimental and Simulation Analysis of Effects of Laser Bending on Microstructures Applied to Advanced Metallic AlloysEsteban Ramos-Moore0Joaquín Hoffmann1Rafael H. M. Siqueira2Sheila Medeiros de Carvalho3Milton S. Fernandes de Lima4Diego J. Celentano5Instituto de Física, Pontificia Universidad Católica de Chile, Vicuña Mackenna 4860, Macul, Santiago 7820436, ChileDepartamento de Ingeniería Mecánica y Metalúrgica, Pontificia Universidad Católica de Chile, Vicuña Mackenna 4860, Macul, Santiago 7820436, ChilePhotonics Division, Instituto de Estudos Avançados, São José dos Campos 12228-001, SP, BrazilPhotonics Division, Instituto de Estudos Avançados, São José dos Campos 12228-001, SP, BrazilPhotonics Division, Instituto de Estudos Avançados, São José dos Campos 12228-001, SP, BrazilCentro de Investigación en Nanotecnología y Materiales Avanzados (CIEN-UC), Pontificia Universidad Católica de Chile, Vicuña Mackenna 4860, Macul, Santiago 7820436, ChileThe aim of this work is the analysis of laser beam forming (LBF) in the bending of two relevant materials used in the transportation industry—interstitial-free (IF) steel and AA6013 high-strength aluminum alloy. Our experiments and numerical simulations consider two different operating scenarios achieved by varying the laser beam scanning velocity using linear paths. The material behavior during this process is described via a coupled thermomechanical-plasticity-based formulation that allows prediction of temperature profiles and bending angles. Metallography, glow discharge optical emission spectroscopy, and X-ray diffraction are used for microstructure characterization. In addition, microstress analyses are performed in order to study the stress behavior of the irradiated zones. It is found that LBF mainly induces grain growth and melting in the case of high surface temperatures. Before melting, the materials developed compressive stresses that could be useful in preventing cracking failures. The resulting bending angles are predicted and experimentally validated, indicating the robustness of the model to estimate LBF effects on advanced alloys. The present analysis relating bending angles together with temperature and microstructure profiles along the thickness of the sheets is the main original contribution of this work, highlighting the need for further modeling refinement of the effects of LBF on advanced alloys to include more microstructural properties, such as grain boundary diffusion and surface roughness.https://www.mdpi.com/2075-4701/11/2/362laser beam formingmicrostructureinterstitial-free steelsaluminum alloysmodeling and numerical simulation
collection DOAJ
language English
format Article
sources DOAJ
author Esteban Ramos-Moore
Joaquín Hoffmann
Rafael H. M. Siqueira
Sheila Medeiros de Carvalho
Milton S. Fernandes de Lima
Diego J. Celentano
spellingShingle Esteban Ramos-Moore
Joaquín Hoffmann
Rafael H. M. Siqueira
Sheila Medeiros de Carvalho
Milton S. Fernandes de Lima
Diego J. Celentano
Experimental and Simulation Analysis of Effects of Laser Bending on Microstructures Applied to Advanced Metallic Alloys
Metals
laser beam forming
microstructure
interstitial-free steels
aluminum alloys
modeling and numerical simulation
author_facet Esteban Ramos-Moore
Joaquín Hoffmann
Rafael H. M. Siqueira
Sheila Medeiros de Carvalho
Milton S. Fernandes de Lima
Diego J. Celentano
author_sort Esteban Ramos-Moore
title Experimental and Simulation Analysis of Effects of Laser Bending on Microstructures Applied to Advanced Metallic Alloys
title_short Experimental and Simulation Analysis of Effects of Laser Bending on Microstructures Applied to Advanced Metallic Alloys
title_full Experimental and Simulation Analysis of Effects of Laser Bending on Microstructures Applied to Advanced Metallic Alloys
title_fullStr Experimental and Simulation Analysis of Effects of Laser Bending on Microstructures Applied to Advanced Metallic Alloys
title_full_unstemmed Experimental and Simulation Analysis of Effects of Laser Bending on Microstructures Applied to Advanced Metallic Alloys
title_sort experimental and simulation analysis of effects of laser bending on microstructures applied to advanced metallic alloys
publisher MDPI AG
series Metals
issn 2075-4701
publishDate 2021-02-01
description The aim of this work is the analysis of laser beam forming (LBF) in the bending of two relevant materials used in the transportation industry—interstitial-free (IF) steel and AA6013 high-strength aluminum alloy. Our experiments and numerical simulations consider two different operating scenarios achieved by varying the laser beam scanning velocity using linear paths. The material behavior during this process is described via a coupled thermomechanical-plasticity-based formulation that allows prediction of temperature profiles and bending angles. Metallography, glow discharge optical emission spectroscopy, and X-ray diffraction are used for microstructure characterization. In addition, microstress analyses are performed in order to study the stress behavior of the irradiated zones. It is found that LBF mainly induces grain growth and melting in the case of high surface temperatures. Before melting, the materials developed compressive stresses that could be useful in preventing cracking failures. The resulting bending angles are predicted and experimentally validated, indicating the robustness of the model to estimate LBF effects on advanced alloys. The present analysis relating bending angles together with temperature and microstructure profiles along the thickness of the sheets is the main original contribution of this work, highlighting the need for further modeling refinement of the effects of LBF on advanced alloys to include more microstructural properties, such as grain boundary diffusion and surface roughness.
topic laser beam forming
microstructure
interstitial-free steels
aluminum alloys
modeling and numerical simulation
url https://www.mdpi.com/2075-4701/11/2/362
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