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U型缺口云杉样本的拉伸撕裂断裂分析

Tensile-Tearing Fracture Analysis of U-Notched Spruce Samples.

作者信息

Torabi Ali Reza, Mohammadi Sobhan, Saboori Behnam, Ayatollahi Majid Reza, Cicero Sergio

机构信息

Fracture Research Laboratory, Faculty of New Sciences and Technologies, University of Tehran, Tehran 14395-1561, Iran.

Center of Excellence in Experimental Solid Mechanics and Dynamics, Fatigue and Fracture Research Laboratory, School of Mechanical Engineering, Iran University of Science and Technology, Tehran 16846, Iran.

出版信息

Materials (Basel). 2022 May 20;15(10):3661. doi: 10.3390/ma15103661.

DOI:10.3390/ma15103661
PMID:35629688
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9147474/
Abstract

Spruce wood () is a highly orthotropic material whose fracture behavior in the presence of U-shaped notches and under combined tensile-tearing loading (so-called mixed-mode I/III loading) is analyzed in this work. Thus, several tests are carried out on U-notched samples with different notch tip radii (1 mm, 2 mm, and 4 mm) under various combinations of loading modes I and III (pure mode I, pure mode III, and three mixed-mode I/III loadings), from which both the experimental fracture loads and the fracture angles of the specimens are obtained. Because of the linear elastic behavior of the spruce wood, the point stress (PS) and mean stress (MS) methods, both being stress-based criteria, are used in combination with the Virtual Isotropic Material Concept (VIMC) for predicting the fracture loads and the fracture angles. By employing the VIMC, the spruce wood as an orthotropic material is modeled as a homogeneous and isotropic material with linear elastic behavior. The stress components required for calculating the experimental values of notch stress intensity factors are obtained by finite element (FE) analyses of the test configuration using commercial FE software from the fracture loads obtained experimentally. The discrepancies between the experimental and theoretical results of the critical notch stress intensity factors are obtained between -12.1% and -15% for the PS criterion and between -5.9% and -14.6% for the MS criterion, respectively. The discrepancies related to fracture initiation angle range from -1.0% to +12.1% for the PS criterion and from +1.5% to +12.2% for the MS criterion, respectively. Thus, both the PS and MS models have good accuracy when compared with the experimental data. It is also found that both failure criteria underestimate the fracture resistance of spruce wood under mixed-mode I/III loading.

摘要

云杉木是一种高度各向异性的材料,本文分析了其在存在U形切口以及在拉伸-撕裂联合载荷(所谓的I/III混合模式载荷)作用下的断裂行为。因此,对具有不同切口尖端半径(1毫米、2毫米和4毫米)的U形切口试样在I型和III型载荷的各种组合(纯I型、纯III型以及三种I/III混合模式载荷)下进行了多项试验,从中获得了试样的试验断裂载荷和断裂角度。由于云杉木的线弹性行为,基于应力的点应力(PS)和平均应力(MS)方法与虚拟各向同性材料概念(VIMC)结合使用,以预测断裂载荷和断裂角度。通过采用VIMC,将作为各向异性材料的云杉木建模为具有线弹性行为的均匀各向同性材料。利用商业有限元软件对试验配置进行有限元(FE)分析,从实验获得的断裂载荷中得到计算切口应力强度因子实验值所需的应力分量。对于PS准则,临界切口应力强度因子的实验结果与理论结果之间的差异在-12.1%至-15%之间;对于MS准则,该差异在-5.9%至-14.6%之间。与断裂起始角度相关的差异,对于PS准则分别在-1.0%至+12.1%之间,对于MS准则分别在+1.5%至+12.2%之间。因此,与实验数据相比,PS和MS模型都具有良好的准确性。还发现,两种失效准则都低估了云杉木在I/III混合模式载荷下的抗断裂能力。

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本文引用的文献

1
Effect of the Drying Method of Pine and Beech Wood on Fracture Toughness and Shear Yield Stress.松木和山毛榉木干燥方法对断裂韧性和剪切屈服应力的影响
Materials (Basel). 2020 Oct 21;13(20):4692. doi: 10.3390/ma13204692.
2
Crack kinking at the tip of a mode I crack in an orthotropic solid.正交各向异性固体中 I 型裂纹尖端处的裂纹弯折
Int J Fract. 2017;207(2):181-191. doi: 10.1007/s10704-017-0227-x. Epub 2017 Jul 11.