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聚酰胺和高密度聚乙烯板材单点渐进成形过程中主应变和厚度减小的最小化

Minimizing the Main Strains and Thickness Reduction in the Single Point Incremental Forming Process of Polyamide and High-Density Polyethylene Sheets.

作者信息

Rosca Nicolae, Oleksik Mihaela, Rosca Liviu, Avrigean Eugen, Trzepieciński Tomasz, Najm Sherwan Mohammed, Oleksik Valentin

机构信息

Faculty of Engineering, "Lucian Blaga" University of Sibiu, Victoriei Bd. 10, 550024 Sibiu, Romania.

Department of Manufacturing Processes and Production Engineering, Faculty of Mechanical Engineering and Aeronautics, Rzeszow University of Technology, al. Powst. Warszawy 8, 35-959 Rzeszów, Poland.

出版信息

Materials (Basel). 2023 Feb 16;16(4):1644. doi: 10.3390/ma16041644.

DOI:10.3390/ma16041644
PMID:36837283
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9963744/
Abstract

Polymeric materials are increasingly used in the automotive industry, aeronautics, medical device industry, etc. due to their advantage of providing good mechanical strength at low weight. The incremental forming process for polymeric materials is gaining increasing importance because of the advantages it offers: relatively complex parts can be produced at minimum cost without the need for complex and expensive dies. Knowing the main strains and especially the thickness reduction is particularly important as it directly contributes to the mechanical strength of the processed parts, including in operation. For the design of experiments, the Taguchi method was chosen, with an L orthogonal array obtained by varying the material on two levels (polyamide and polyethylene) and the other three parameters on three levels: punch diameter (6 mm, 8 mm and 10 mm), wall angle (50°, 55° and 60°) and step down (0.5 mm, 0.75 mm and 1 mm). The output parameters were strain in the x direction, strain in the y direction, major strain, minor strain, shear angle and thickness reduction. Two analyses were conducted: signal-to-noise ratio analysis with the smaller-is-better condition and analysis of variance. The optimum values for which the thickness was reduced were the following: wall angle of 50°, punch diameter of 10 mm and step down of 0.75 mm.

摘要

由于聚合物材料具有在低重量下提供良好机械强度的优势,它们在汽车工业、航空航天、医疗器械行业等中越来越多地被使用。聚合物材料的增量成型工艺因其提供的优势而变得越来越重要:无需复杂且昂贵的模具,就能以最低成本生产相对复杂的零件。了解主要应变,尤其是厚度减小情况尤为重要,因为它直接影响加工零件的机械强度,包括在实际使用中。在实验设计方面,选择了田口方法,通过在两个水平上改变材料(聚酰胺和聚乙烯)以及在三个水平上改变其他三个参数来获得一个L正交阵列:冲头直径(6毫米、8毫米和10毫米)、壁角(50°、55°和60°)以及步距(0.5毫米、0.75毫米和1毫米)。输出参数包括x方向应变、y方向应变、主应变、次应变、剪切角和厚度减小量。进行了两项分析:在越小越好条件下的信噪比分析和方差分析。厚度减小的最佳值如下:壁角50°、冲头直径10毫米和步距0.75毫米。

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