Study on Mode Ⅲ Stress Intensity Factor at Tip of Nano Cracks Emanating from a Circular Hole

Abstract

Abstract: The fracture performances of nano cracks emanating from circular holes under far-field antiplane shear were investigated. Based on the Gurtin-Murdoch surface elasticity theory and conformal mapping technique， an analytical solution of the whole-field stress for such heterogeneous materials was obtained by using complex elasticity theory. The closed-form formula for the mode Ⅲ stress intensity factors at tip of the nano cracks was presented. The stress field distributions of the hole were studied based on the obtained formulas. The size-dependence of the stress intensity factors and the influences of the relative size of the hole on the stress intensity factors at crack tips were also discussed. The numerical results reveal that the stress field of the hole shows a nonmonotonic distribution， and the influences of the surface effect on the stress are quite different at different positions on the holes. When the size of the hole-cracks is on the nanometer scale， the stress intensity factors at crack tips show a significant size dependent effect. The influences of the relative size of the holes on the stress intensity factors are restricted by the surface property. At the same time， the influences of the surface property on the stress intensity factors depend on the relative size of the holes too.

Key words: surface effect, nano cracked circular hole, mode Ⅲ crack, stress intensity factor

摘要： 研究了纳米尺度圆孔孔边裂纹在远场反平面剪切载荷作用下的断裂性能。基于Gurtin-Murdoch表面弹性理论和保角映射技术，利用复变弹性理论获得了该类非均匀材料应力场的解析解，给出了裂尖Ⅲ型应力强度因子的闭合解。基于所得解答，研究了孔边的应力场分布规律，讨论了裂尖应力强度因子的尺寸依赖效应以及圆孔相对尺寸对应力强度因子的影响。研究结果表明：孔边应力场呈现非单调分布，表面效应对孔边不同位置应力的影响程度不同；当圆孔裂纹的尺寸在纳米量级时，裂尖应力强度因子具有显著的尺寸依赖效应；圆孔相对裂纹尺寸对裂尖应力强度因子的影响规律受表面性能的制约，同时表面性能对应力强度因子的影响也取决于圆孔的相对尺寸。

关键词: 表面效应, 纳米尺度孔边裂纹, Ⅲ型裂纹, 应力强度因子

CLC Number:

O346

XIAO Junhua1;CUI Youqiang1;XU Yaoling1;ZHANG Fucheng2. Study on Mode Ⅲ Stress Intensity Factor at Tip of Nano Cracks Emanating from a Circular Hole[J]. China Mechanical Engineering.

肖俊华1;崔友强1;徐耀玲1;张福成2. 纳米尺度孔边裂纹裂尖Ⅲ型应力强度因子研究[J]. 中国机械工程.

References

[1]郁大照，陈跃良，张勇，等. 螺接搭接件的载荷传递特性试验及三维有限元分析 [J］. 中国机械工程， 2010， 21（19）： 2273-2278.
YU Dazhao， CHEN Yueliang， ZHANG Yong， et al. Study on Load Transfer Properties of Bolted Joints Based on Experiments and Three-imensional Finite Element [J］. China Mechanical Engineering， 2010， 21（19）： 2273-2278.
[2]杨世强，王蓓蓓. 轻型机械臂的轻量化结构设计优化方法 [J］. 中国机械工程， 2016， 27（19）： 2575-2580.
YANG Shiqiang， WANG Beibei. Lightweight Structure Design and Optimization Method for a Light Mobile Manipulator [J］. China Mechanical Engineering， 2016， 27（19）： 2575-2580.
[3]CHEN Y D，FENG Q，ZHENG Y R，et al. Formation of Hole-edge Cracks in a Combustor Liner of an Aero Engine [J］. Engineering Failure Analysis， 2015， 55：148-156.
[4]BOLJANOVIC S，MAKSIMOVIC S，DJURIC M. Fatigue Strength Assessment of Initial Semi-elliptical Cracks Located at a Hole [J］. International Journal of Fatigue， 2016， 92：548-556.
[5]CHAVES V，BERETTA G，NAVARRO A. Biaxial Fatigue Limits and Crack Directions for Stainless Steel Specimens with Circular Holes [J］. Engineering Fracture Mechanics， 2017， 174：139-154.
[6]高克玮，陈奇志，褚武扬，等. 纳米级解理微裂纹的形核和扩展 [J］. 中国科学（A辑）， 1994， 24（9）： 993-1000.
GAO Kewei， CHEN Qizhi， CHU Wuyang， et al. Nucleation and Expansion of Nanoscale Cleavage Microcracks[J］.Science in China(A Series)，1994， 24（9）：993-1000.
[7]MACHOV?倖
A， BELTZ G E. Ductile-brittle Behavior of （0 0 1） [1 1 0］ Nano-cracks in bcc Iron [J］. Materials Science and Engineering A， 2004， 387/389（1-2）：414/418.
[8]邢永明，戴福隆，杨卫. 准解理微裂纹裂尖纳观变形场的实验研究 [J］. 中国科学（A辑）， 2000， 30（8）： 721-726.
XING Yongming，DAI Fulong，YANG Wei. Experimental Study on the Deformation Field of Quasi-cleavage Microcrack Crack Tip[J］.Science in China（A Series），2000，30（8）：721-726.
[9]邵宇飞，王绍青. 基于准连续介质方法模拟纳米多晶体Ni中裂纹的扩展 [J］. 物理学报， 2010， 59（10）： 7258-7265.
SHAO Yufei， WANG Shaoqing. Quasicontinuum Simulation of Crack Propagation in Nanocrystalline Ni [J］. Acta Physica Sinica， 2010， 59（10）： 7258-7265.
[10]LE J L， BAZANT Z P， BAZANT M Z. Unified Nano-mechanics Based Probabilistic Theory of Quasibrittle and Brittle Structures： I. Strength， Static Crack Growth， Lifetime and Scaling [J］. Journal of the Mechanics and Physics of Solids， 2011， 59（7）： 1291-1321.
[11]JONES R， PITT S， HUI D， et al. Fatigue Crack Growth in Nano-composites [J］. Composite Structures， 2013， 99（5）： 375-379.
[12]LI J J， SOH A K， CHEN S H. A Coupling Crack Blunting Mechanism in Nanocrystalline Materials by Nano-grain Rotation and Shear-coupled Migration of Grain Boundaries [J］. Materials Letters， 2014， 137： 218-220.
[13]LUO J， LI Z H， XIAO Z M. On the Stress Field and Crack Nucleation Behavior of a Disclinated Nanowire with Surface Stress Effects [J］. Acta Mechanica， 2014， 225（11）： 3187-3197.
[14]GAO Y J， DENG Q Q， HUANG L L， et al. Atomistic Modeling for Mechanism of Crack Cleavage Extension on Nano-scale [J］. Computational Materials Science， 2017， 130：64-75.
[15]GURTIN M E， MURDOCH A I. A Continuum Theory of Elastic Material Surfaces [J］. Archive for Rational Mechanics and Analysis， 1975， 57（4）：291-323.
[16]WANG X， ZHOU K， WU M S. Interface Cracks with Surface Elasticity in Anisotropic Bimaterials [J］. International Journal of Solids and Structures， 2015， 59：110-120.
[17]NGUYEN T B， RUNGAMORNRAT J， SENJUNTICHAI T， et al. FEM-SGBEM Coupling for Modeling of Mode-I Planar Cracks in Three-dimensional Elastic Media with Residual Surface Tension Effects [J］. Engineering Analysis with Boundary Elements， 2015， 55：40-51.
[18]XU J Y， DONG C Y. Surface and Interface Stress Effects on the Interaction of Nano-inclusions and Nano-cracks in an Infinite Domain under Anti-plane Shear[J］. International Journal of Mechanical Sciences， 2016， s111-s112：12-23.
[19]WANG X， SCHIAVONE P. Bridged Cracks of Mode Ⅲ with Surface Elasticity [J］. Mechanics of Materials， 2016， 95：125-135.
[20]WANG C， WANG X. A Mode Ⅲ Rate-dependent Bridged Crack with Surface Elasticity [J］. Mechanics of Materials， 2017， 108：107-119.
[21]LUO J， WANG X. On the Anti-plane Shear of an Elliptic Nano Inhomogeneity [J］. European Journal of Mechanics-A/Solids， 2009， 28（5）：926-934.
[22]WANG Y J，GAO C F. The Mode Ⅲ Cracks Originating from the Edge of a Circular Hole in a Piezoelectric Solid[J］. International Journal of Solids and Structures， 2008， 45（16）：4590-4599.
[23]YANG J， LI X. Analytic Solutions of Problem about a Circular Hole with a Straight Crack in One-dimensional Hexagonal Quasicrystals with Piezoelectric Effects [J］. Theoretical and Applied Fracture Mechanics， 2016， 82：17-24.
[24]MUSKHELISHVILI N I. Some Basic Problems of the Mathematical Theory of Elasticity [M］. Groningen： Noordhoff， 1953.