Numerical Analysis of Fatigue Life and strength of AA5052 Aluminum Alloy Reinforced with ZrO2, TiO2 and Al2O3 Nanoparticles

Diyala Journal of Engineering Sciences Pub Date : 2022-06-01 DOI:10.24237/djes.2022.15208

Baqir Ibraheem, Salem F. Salman, Abdul-jabar H. Ali

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Abstract

In this study, the finite element method using ANSYS workbench 16.1 has been successfully used to predict the fatigue life, fatigue strength, and the factors of safety for the as cast AA5052 as arrow matrix and its composites: AA5052/7 wt% ZrO2, AA5052/7 wt% TiO2 and AA5052/7 wt% Al2O3. The Finite Element Analysis (FEA) model was building according to dimensions of the experimental fatigue specimen. The total number of elements was 504 elements with a total number of nodes of 2572 nodes. The numerical fatigue test was processed under static structural analysis, and it has been analyzed using fatigue tool on ANSYS, Goodman theory was used for the prediction of life. The FEM using ANSYS.16.1 workbench simulation showed a good agreement with the experimental results for all the stress life curves and the highest difference in fatigue life was 17% and the lowest was 1.4%, for ZrO2 composite, while the maximum overall average error was 2.031% for AA5052 and the lowest was 0.378%, for Al2O3 composite. The maximum difference about 4.14 % between the experimental and numerical fatigue strength at 107 cycles for the row matrix and less than for the composites, also the minimum factor of safety for the AA5052 alloy is 0.8327 and for AA5052/7 wt% ZrO2 composite is 1.0709 while for both AA5052/7wt%TiO2 and AA5052/7 wt% Al2O3 composites are 1.0707 at specific design life.

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ZrO2、TiO2和Al2O3纳米颗粒增强AA5052铝合金疲劳寿命和强度的数值分析

利用ANSYS workbench 16.1，成功地对铸态AA5052箭形基体及其复合材料:AA5052/7 wt% ZrO2、AA5052/7 wt% TiO2和AA5052/7 wt% Al2O3的疲劳寿命、疲劳强度和安全系数进行了预测。根据试验疲劳试样的尺寸建立有限元分析模型。元素总数为504个，节点总数为2572个。在静力结构分析的条件下进行了数值疲劳试验，并利用ANSYS的疲劳分析工具对其进行了分析，采用Goodman理论对其寿命进行了预测。采用ANSYS.16.1 workbench进行有限元模拟，结果表明，各应力寿命曲线与试验结果吻合较好，ZrO2复合材料的疲劳寿命最大误差为17%，最小误差为1.4%，而AA5052复合材料的整体平均误差最大为2.031%，Al2O3复合材料的整体平均误差最小为0.378%。在107次循环时，排基体的实验疲劳强度与数值疲劳强度之间的最大差异约为4.14%，而复合材料的最小差异较小;在特定设计寿命下，AA5052合金的最小安全系数为0.8327,AA5052/7wt% ZrO2复合材料的最小安全系数为1.0709，而AA5052/7wt%TiO2和AA5052/7wt% Al2O3复合材料的最小安全系数为1.0707。

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Diyala Journal of Engineering Sciences

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