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.
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机译:激光喷发成型(LPF)适用于成型板金属而不需要模具/模具并且不引起高温。用于估算LPF弯曲曲率的分析模型是方便和必要的,以便更好地理解所涉及的物理过程。在本文中,我们描述了基于内部力平衡的新分析模型和LPF中的能量变换。进行2024型铝合金片材的实验,厚度为1-3毫米,以验证分析模型。结果表明,对于1毫米和3毫米的厚薄板,通过分析模型获得的曲率从-14×10-4mm-1和-1×10-4 mm-1变为55×10-4 mm -1和-21×10-4 mm-1分别随着激光能量的增加,这与实验趋势一致。因此,当应力梯度机制(SGM)或冲击弯曲机构(SBM)压倒地位,与实验数据相比,分析模型可以给出相对准确的预测曲率。在SGM和SBM可比较的那些条件下,由于材料内的复合应力分布和这些条件下的复合能耦合过程,模型的精度低。
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