6533b833fe1ef96bd129c1d7
RESEARCH PRODUCT
Finite element analysis of laser shock peening of 2050-T8 aluminum alloy
Vincent VignalPatrice PeyreHongbin SongNeila HfaiedhI. PopaVincent Jisubject
DiffractionMatériaux [Sciences de l'ingénieur]Materials scienceResidual stressIndustrial and Manufacturing Engineering[SPI.MAT]Engineering Sciences [physics]/MaterialsMaterials Science(all)Residual stressModelling and SimulationHomogeneity (physics)Aluminium alloyGeneral Materials ScienceLaser shock peeningComposite materialAnisotropyMécanique [Sciences de l'ingénieur]business.industryMechanical EngineeringSurface stressFinite element analysisPeeningStructural engineering[SPI.MECA]Engineering Sciences [physics]/Mechanics [physics.med-ph]Finite element methodMechanics of MaterialsModeling and Simulationvisual_artvisual_art.visual_art_mediumbusinessdescription
Laser shock processing is a recently developed surface treatment designed to improve the mechanical properties and fatigue performance of materials, by inducing a deep compressive residual stress field. The purpose of this work is to investigate the residual stress distribution induced by laser shock processing in a 2050-T8 aeronautical aluminium alloy with both X-ray diffraction measurements and 3D finite element simulation. The method of X-ray diffraction is extensively used to characterize the crystallographic texture and the residual stress crystalline materials at different scales (macroscopic, mesoscopic and microscopic).Shock loading and materials’ dynamic response are experimentally analysed using Doppler velocimetry in order to use adequate data for the simulation. Then systematic experience versus simulation comparisons are addressed, considering first a single impact loading, and in a second step the laser shock processing treatment of an extended area, with a specific focus on impact overlap. Experimental and numerical results indicate a residual stress anisotropy, and a better surface stress homogeneity with an increase of impact overlap.A correct agreement is globally shown between experimental and simulated residual stress values, even if simulations provide us with local stress values whereas X-ray diffraction determinations give averaged residual stresses.; International audience; Laser shock processing is a recently developed surface treatment designed to improve the mechanical properties and fatigue performance of materials, by inducing a deep compressive residual stress field. The purpose of this work is to investigate the residual stress distribution induced by laser shock processing in a 2050-T8 aeronautical aluminium alloy with both X-ray diffraction measurements and 3D finite element simulation. The method of X-ray diffraction is extensively used to characterize the crystallographic texture and the residual stress crystalline materials at different scales (macroscopic, mesoscopic and microscopic).Shock loading and materials’ dynamic response are experimentally analysed using Doppler velocimetry in order to use adequate data for the simulation. Then systematic experience versus simulation comparisons are addressed, considering first a single impact loading, and in a second step the laser shock processing treatment of an extended area, with a specific focus on impact overlap. Experimental and numerical results indicate a residual stress anisotropy, and a better surface stress homogeneity with an increase of impact overlap.A correct agreement is globally shown between experimental and simulated residual stress values, even if simulations provide us with local stress values whereas X-ray diffraction determinations give averaged residual stresses.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2015-01-01 |