Formulation of stress concentration factor and shape optimization of gooseneck joint under uniaxial tensile load

Transactions of the JSME (in Japanese) Pub Date : 1900-01-01 DOI:10.1299/transjsme.19-00388

Takumi Nakamura, Y. Arai, Tomohisa Kojima, T. Tsuji

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Abstract

If we use wood as a structural material, we can reduce carbon dioxide emission. In Japan, houses have been made by wood traditionally and wood is used as a structural material such as pillar and beam. In order to use wood as a structural material, a joint is necessary. The shapes of these traditional joints are determined empirically and used without any analytical evaluation such as stress analysis. Therefore, stress analysis is necessary in order to use such joints efficiently. In this study, we make stress analysis of gooseneck joint, which is one of the typical joint in japan. The strain distributions of the joint are measured, and the stress distributions are obtained by digital image correlation method (DIC). We also simulate gooseneck joint subjected to tensile load by using FEM. A male part and a female part are contacted in the joint region. Comparing FEM results to DIC results, the validities of both results are confirmed. Moreover, we propose the formulae to obtain the joint stress concentration factor by using the FEM results. The optimum shape, which gives the least maximum stress under uniaxial loading, is obtained by using the proposed formulae.

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单轴拉伸载荷下鹅颈接头应力集中系数的计算及形状优化

如果我们使用木材作为结构材料，我们可以减少二氧化碳的排放。在日本，房屋传统上是由木材建造的，木材被用作结构材料，如支柱和梁。为了使用木材作为结构材料，接合是必要的。这些传统节点的形状是经验确定的，没有任何分析评价，如应力分析。因此，为了有效地利用这种节理，有必要进行应力分析。本文对日本典型的鹅颈关节进行了应力分析。测量了接头的应变分布，并利用数字图像相关法(DIC)得到了接头的应力分布。采用有限元法对鹅颈节在拉伸载荷作用下进行了数值模拟。在所述关节区域内接触一公部和一母部。将有限元计算结果与DIC计算结果进行比较，验证了两者的正确性。在此基础上，提出了利用有限元计算结果计算节点应力集中系数的公式。在单轴载荷作用下，得到最大应力最小的最优形状。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Transactions of the JSME (in Japanese)

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