Overview of laser-welded thin-walled joints fatigue performance and a statistical method for defect analysis

Q4 Engineering

Rakenteiden Mekaniikka Pub Date : 2020-09-04 DOI:10.23998/rm.77612

R. Kokko, J. Vaara, T. Kuivaniemi, T. Frondelius

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引用次数: 0

Abstract

Welding always has a deteriorating effect on fatigue strength in structures under dynamic loading. Weld joints induce discontinuity in structure geometry and the microstructure. Welding induced discontinuity, and defects allow for potential fatigue cracks that lead to the failure of welded parts or structures. The laser welding process differs from conventional arc welding in process and joint type. The most significant advantage in laser welding comes from the deep penetrating mode of welding, which also brings challenges to the soundness of the weld. The benefits of laser welding are most evident in the manufacture of sheet metal products such as sandwich panels. In literature, laser welding is generally dealt with by using different parts of the overall process without taking the fatigue point of view into account. In this article, the process of laser welding is discussed, while keeping fatigue strength in perspective. The fatigue data of laser welded joints is studied in order to find defect distribution that explains fatigue strength distribution in tests. The suitability of traditional fatigue assessment for laser welding is also discussed.

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激光焊接薄壁接头疲劳性能综述及缺陷分析的统计方法

在动态载荷作用下，焊接对结构的疲劳强度总是有恶化的影响。焊接接头会导致结构几何形状和微观结构的不连续性。焊接引起的不连续性和缺陷会导致潜在的疲劳裂纹，从而导致焊接零件或结构失效。激光焊接工艺在工艺和接头类型上与传统电弧焊接不同。激光焊接最显著的优势来自焊接的深穿透模式，这也给焊缝的稳固性带来了挑战。激光焊接的好处在诸如夹芯板之类的金属板产品的制造中最为明显。在文献中，激光焊接通常是通过使用整个过程的不同部分来处理的，而不考虑疲劳的观点。本文讨论了激光焊接的工艺过程，并从保持疲劳强度的角度出发。对激光焊接接头的疲劳数据进行了研究，以找出在试验中解释疲劳强度分布的缺陷分布。还讨论了传统疲劳评定方法在激光焊接中的适用性。

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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来源期刊

Rakenteiden Mekaniikka Engineering-Mechanical Engineering

CiteScore

0.50

自引率

0.00%

发文量

审稿时长

16 weeks