Abstract
Laser peen forming (LPF) is suitable for shaping sheet metals without the requirement for die/mold and without causing high temperatures. An analytical model for estimating the bending curvatures of LPF is convenient and necessary for better understanding of the physical processes involved. In this paper, we describe a new analytical model based on internal force balance and the energy transformation in LPF. Experiments on 2024 aluminum alloy sheets of 1–3 mm thickness were performed to validate the analytical model. The results showed that for 1 mm and 3 mm thick–thin plates, the curvature obtained by the analytical model changes from −14 × 10−4 mm−1 and −1 × 10−4 mm−1 to 55 × 10−4 mm−1 and −21 × 10−4 mm−1, respectively, with the increase of laser energy, which is consistent with the experimental trend. So, when either the stress gradient mechanism (SGM) or the shock bending mechanism (SBM) overwhelmingly dominated the forming process, the analytical model could give relatively accurate predicted curvatures compared with the experimental data. Under those conditions where SGM and SBM were comparable, the accuracy of the model was low, because of the complex stress distributions within the material, and the complex energy coupling process under these conditions.
Highlights
We present a new analytical model for the prediction of both convex and concave deformation of metallic sheets through laser peen forming
stress gradient mechanism (SGM) and shock bending mechanism (SBM) coexist in laser peen forming and their combined effects determine the obtained deformation of targets, that is to say, k0 = k01 + k02
2024 aluminum alloy obtained through experiments and the analytical model
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Hu et al [4] observed both concave and convex curvature formation in laser peen forming of aluminum sheets of 0.5 mm to 2.25 mm in thickness. We present a new analytical model for the prediction of both convex and concave deformation of metallic sheets through laser peen forming. When the target sheet is thick or the laser intensity is moderate, the laserlaser-induced shock wave can only induce plastic deformation and compressive residual induced shock wave can only induce plastic deformation and compressive residual stress stress in alayer thin of layer the target surface and elastic deformation is developed beneath the in a thin theof target surface and elastic deformation is developed beneath the plastic plastic deformation zone, which will acause a negative moment Under this condition, the sheet will be bent in a convex mode.
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