Abstract
The present study focused on the behaviour of the AW-6060 aluminium alloy in peak temper condition T6 under a wide range of loads: tensile loading, projectile and explosion. The alloy is used as a structural component of civil engineering structures exposed to static or dynamic loads. Therefore, it was crucial to determine the material’s behaviour at low and intermediate rates of deformation. Despite the fact that the evaluation of the strain rate sensitivity of the AW-6060 aluminium alloy has already been discussed in literature, the authors of this paper wished to further investigate this topic. They conducted tensile tests and confirmed the thesis that the AW-6060 T6 aluminium alloy has low strain rate sensitivity at room temperature. In addition, the fracture surfaces subjected to different loading (tensile loading, projectile and explosion) were investigated and compared using a scanning electron microscope, because the authors of this paper were trying to develop a new methodology for predicting how samples had been loaded before failure occurred based on scanning electron microscopy (SEM) micrographs. Projectile and explosion tests were performed mainly for the SEM observation of the fracture surfaces. These tests were unconventional and they represent the originality of this research. It was found that the type of loading had an impact on the fracture surface.
Highlights
The use of civil engineering structures made of aluminium alloys is on the rise
Alloy and a proof that it belonged to the aluminium–magnesium–silicon family (6000 series)
In this thecomposition authors analysed theimportant two at thealuminium top and on the Thesection chemical provided information The about thegraphs investigated right-hand side of the micrographs present grey-scale intensity profiles (grey-scale intensity alloy and a proof that it belonged to the aluminium–magnesium–silicon family (6000 series)
Summary
The use of civil engineering structures made of aluminium alloys is on the rise. The useful and well-known structural applications of aluminium are presented by Mazzolani [1]. Aluminium alloys may be used in complex multi-layered structures, for example, aluminium-concrete composite beams [2,3,4], aluminium-timber composite beams [5] and blast- or impact-resistant panels [6]. These structures are exposed to static or dynamic loads. The authors of this paper chose to investigate the AW-6060 T6 (AW-AlMgSi) aluminium alloy. It is a wrought heat-treatable alloy suitable for structural applications. The alloys belonging to the 6000 series contain relatively small amounts of magnesium and silicon, and additions such as
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