电偶腐蚀对铝与不锈钢螺栓连接强度及破坏影响的对比研究

IF 3.8 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Afaf Saai , Virgile Delhaye , Torstein Lange , Trond Furu , Kristian Aamot , John Lein
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引用次数: 0

摘要

本文研究了双金属嵌套对铝-不锈钢搭接剪切螺栓组合件的腐蚀、材料降解、承载能力、应力分布、应变分布和破坏的影响。铝板和不锈钢板的单螺栓搭接剪切组件在两种设置下进行,其中一种使用双金属插入。考虑到铝在铝-不锈钢电偶中起到牺牲阳极的作用,还可以考虑采用单螺栓搭接剪切组合连接两块铝板作为参考。实验测量采用拉伸-剪切试验方法确定三种不同的条件:干燥条件和两种腐蚀状态,分别对应于6周和16周的加速腐蚀试验。为了更好地理解预紧力和摩擦对腐蚀产物形成的影响,研究人员在不同预紧力和摩擦系数下进行了有限元模拟。研究表明,腐蚀对加载能力、螺栓旋转和破坏模式有显著影响。经过6周加速腐蚀试验后,铝-铝组件和铝-不锈钢组件的拉伸-剪切力与干燥条件下的拉伸-剪切力相比有所增加。拉伸-剪切力的增加与腐蚀产物的形成有关,影响了接触表面的预紧力和摩擦行为。与实验观察结果一致,有限元模拟表明,随着摩擦力的增加,拉剪力增加。与未腐蚀的组件相比,双金属嵌套的应用大大降低了腐蚀对腐蚀组件的拉伸剪切力测量的影响。然而,由于双金属嵌套对螺栓旋转和应力分布的影响,与不含双金属嵌套的铝-不锈钢组合相比,其受力-位移响应和破坏模式受到影响。这需要在设计不同材料的螺栓组合时加以考虑。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Comparative study of the effects of galvanic corrosion on the strength and the failure of aluminium and stainless steel bolted joints

This paper investigates the effects of bimetallic insert on corrosion, material degradation, loading capacity, stress distribution, strain distribution and failure of aluminium-stainless steel lap shear bolted assemblies. The single bolt lap shear assemblies of aluminium and stainless steel plates were performed in two settings in one of them a bimetallic insert was used. Considering that the aluminium plays the role of sacrificial anode in the aluminium-stainless steel galvanic couple, a single bolt lap shear assembly joining two aluminium plates is also considered as a reference. The experimental measurements were determined by tensile-shear testing method for three different conditions: dry condition and two corrosion states corresponding to 6 weeks and 16 weeks of accelerated corrosion tests. To support understanding of the effects of preload and friction changes due to the formation of corrosion products, finite element simulations were performed with varying preloads and friction coefficients. The study demonstrated significant effects of corrosion on loading capacity, bolt rotation and failure mode. The tensile-shear forces measured for the aluminium-aluminium assembly and aluminium-stainless steel assembly after 6 weeks of accelerated corrosion tests increased compared to the tensile-shear forces measured in dry condition. The increase in tensile-shear forces was related to the formation of corrosion products, affecting the preload and the frictional behaviour of the contacting surfaces. In agreement with experimental observations, finite element simulations demonstrated an increase in the tensile-shear force with the increase of frictional forces. The application of bimetallic inserts considerably reduces the effect of corrosion on the measured tensile-shear force of corroded assembly compared to non-corroded assembly. However, it affects the force-displacement response and failure mode compared to the response of aluminium-stainless steel assembly without bimetallic insert due to its effects on the bolt rotation and stress distribution. This needs to be considered in the design of dissimilar material bolted assembly.

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来源期刊
CiteScore
7.10
自引率
9.80%
发文量
58
审稿时长
44 days
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