双叶木梁的力学行为研究和裂纹扩展的多尺度模拟

S. Bisong, V. V. Lepov, A. R. Etinge
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摘要

研究了喀麦隆西南部地区当地木材品种(Bilinga)在雨季和旱季的力学行为以及木梁在弯曲荷载下的力学行为。采用三点抗弯试验来确定所研究木材的机械性能。ANSYS 2020 R1 有限元 (FE) 软件用于宏观层面的数值模拟,并使用了 2019 版中引入的一项名为 "智能裂纹生长 "的最新技术。几何形状在 SolidWorks 中建模,每个样品的初始裂纹长度分别为 4 毫米和 8 毫米,然后导入 ANSYS workbench 进行进一步分析。应力强度因子(SIF)决定了材料在线性弹性断裂力学(LEFM)作用下的断裂韧性,其中临界应力强度变量称为 KIc。疲劳裂纹生长采用帕里斯定律建模。裂纹生长模拟基于模式 I 裂纹试样,初始裂纹长度分别为 4 毫米和 8 毫米。中尺度和微尺度裂纹生长随机多尺度建模用于比较异质材料的裂纹生长率,并考虑了 Bilinga 木材的微观结构和断裂机制。在具有特征尺寸的裂纹和孔隙阵列中对裂纹生长进行随机建模的结果表明,模拟结果与 FE 建模结果接近。因此,在中尺度和微尺度上对木材裂纹生长的随机模拟表明,由于尺度-时间层次结构的存在,局部应力强度因子较低,裂纹生长速度较慢。宏观尺度的裂纹生长速率 vcr 在 0.845 - 0.9 × 10-3 米/秒之间,与断裂韧性 KIc 的宏观值相对应。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Study of the mechanical behavior and multiscale simulation of the crack propagation in a bilinga wooden beam
The mechanical behavior of local wood species (Bilinga) in the south west region in Cameroon during rainy and dry seasons and the mechanical behavior of wooden beam under bend loading are studied. The three points flexural tests were used to determine the mechanical properties of the wood under study. ANSYS 2020 R1 finite element (FE) software is used for numerical simulations at a macroscopic level using one of the newer technologies called Smart crack growth, which was introduced in the 2019 version. The geometry was modeled in SolidWorks with an initial crack length of 4 and 8 mm introduced in each sample and then imported to ANSYS workbench for further analysis with ANSYS which has all the tools to perform linear fracture. The stress intensity factor (SIF) determines the fracture toughness of a material which is subjected to linear-elastic fracture mechanics (LEFM) where a variable of the critical stress intensify is denoted as KIc. The fatigue crack growth was modeled using Paris’ law. The crack growth was simulated based on Mode I crack specimen with an initial crack length of 4 and 8 mm, respectively. The stochastic multiscale modeling of crack growth on meso- and microscale is used to compare the crack growth rate in the approach of a heterogeneous material and taking into account the microstructure and fracture mechanism of the Bilinga wood. The results of stochastic modeling of the crack growth in the array of cracks and pores of a characteristic size shows that the simulation is close to FE-modeling results. Therefore, the stochastic simulation of the crack growth in wood at meso- and microscale shows the lower local stress intensity factors and slower crack growth due to the existence of the scale-time hierarchy. The crack growth rate vcr at a macroscale ranges within 0.845 – 0.9 × 10–3 m/sec which corresponds to the macroscopic value of the fracture toughness KIc.
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