通过数字辅助技术研究用二氧化钛分散体增强的 AA6063 基金属基复合材料的机械、摩擦学和微观结构特性

IF 2 Q2 ENGINEERING, MECHANICAL Frontiers in Mechanical Engineering Pub Date : 2024-06-14 DOI:10.3389/fmech.2024.1393959
Jagannath I. Pattar, D. Ramesh, R. Malghan, Ajay Kumar, Pawan Kumar, V. H. M.
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引用次数: 0

摘要

通过搅拌铸造将不同体积分数的二氧化钛分散体分散到 AA6063 基体中,制备了铝金属基复合材料 (AMC),并对其进行了工艺-结构相关性研究。本文根据重量比考虑了四种不同的样品:99Al-1TiO2、97Al-3TiO2、95Al-5TiO2 和原样 AA6063。测定了它们的机械性能,即显微硬度、拉伸强度和摩擦学行为。此外,还分析了样品的微观结构。结果表明,添加 5% 的 TiO2 颗粒可使 AA6063 基体容纳更高的应变能,同时提供产生位错和亚结构所需的驱动力。因此,考虑到塑性变形,极限拉伸强度σut 随着 TiO2 的添加(重量百分比)而逐渐增加。95Al-5TiO2 样品的流动曲线显示出最高的σut 值,而原样接收的 AA6063 基体则显示出最低的σut 值。就线性弹性变形而言,与 AMMC 样品相比,在所有 TiO2 重量百分比值下,AA6063 的屈服强度(σys)最低;不过,AMMC 样品之间的σys 变化很小。样品的显微硬度随着 TiO2 的添加而逐渐增加,95Al-5TiO2 的断裂面积减少百分比最大。Taguchi L9 阵列和工艺参数方差分析表明,材料磨损主要受正常载荷的影响,其次是 TiO2 重量百分比和滑动速度。在所有 AMMC 样品中都观察到了磨损表面特征,如微空洞、分层、微裂纹和磨损碎屑。整体强度的提高归因于添加分散体的效果。在熔体凝固过程中,TiO2 颗粒超过/夹住并阻碍了晶粒的生长,导致晶粒尺寸细化。
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Investigation of AA6063-based metal–matrix composites reinforced with TiO2 dispersoids through digitally assisted techniques for mechanical, tribological, and microstructural characterizations
Aluminum metal–matrix composites (AMMCs) were prepared by dispersing TiO2 dispersoids of different volume fractions into an AA6063 matrix via stir casting and subjected to process–structure correlation studies. Four different samples based on weight ratio were considered herein: 99Al-1TiO2, 97Al-3TiO2, 95Al-5TiO2, and the as-received AA6063. Their mechanical properties namely, microhardness, tensile strength, and tribological behavior, were determined. In addition, the microstructure of the samples was also analysed. It was observed that the addition of 5% TiO2 particles enabled the AA6063 matrix to accommodate a higher strain energy while providing the required driving force to generate dislocations and substructures. Therefore, considering the plastic deformation, the ultimate tensile strength σut increased gradually with the addition of TiO2 (in weight%). The flow curves of the 95Al-5TiO2 sample showed the highest value of σut, whereas the as-received AA6063 matrix exhibited the lowest value. For linear elastic deformation, AA6063 showed the lowest yield strength (σys) as compared to the AMMC samples for all TiO2 weight% values; however, the variation in σys among the AMMC samples was minimal. The microhardness of the samples increased gradually with the addition of TiO2, and the percentage reduction in area at the fracture was largest for 95Al-5TiO2. The Taguchi’s L9 array and variance analysis of the process parameters indicated that the material wear was largely affected by the normal load, followed by weight% of TiO2 and sliding speed. Wear surface characteristics, such as microvoids, delamination, microcracks, and wear debris, were qualitatively observed in all the AMMC samples. The overall strength improvement was attributable to the effects of addition of the dispersoids. During melt solidification, the TiO2 particles surpassed/pinned and hindered the grain growth, resulting in grain-size refinement.
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来源期刊
Frontiers in Mechanical Engineering
Frontiers in Mechanical Engineering Engineering-Industrial and Manufacturing Engineering
CiteScore
4.40
自引率
0.00%
发文量
115
审稿时长
14 weeks
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