MECHANISM ANALYSIS OF THICKNESS EFFECT ON MIXED MODE Ⅰ/Ⅱ FRACTURE OF LC4-CS ALUMINUM ALLOY

Mixed mode Ⅰ/Ⅱ fracture erperiments of LC4-CS aluminum alloy were conductedby using tension--shear specimens with thicknesses of 2, 4, 8 and 14mm. Fracturemechanisms of thickness effect on mixed mode Ⅰ/Ⅱ fracture were first examined fromfracture surface morphology to correlate with the macroscopic fracture behavior andstress state. It is found that specimen thickness has a strong influence on mixed modefracture. As thickness varies from thin to thick the macroscopic fracture surfacesappear the characteristics of plane stress state (2mm, 4mm--thick specimen), three--dimensional stress state (8mm--thick specimens), and plane strain state (14mm--thickspecimens), respectively. The specimens of all kinds of thicknesses are typical of ten-sile type failure under mode Ⅰ loading condition and shear type failure under mode Ⅱloading condition. Two distinct features coexist on the fracture surfaces under mixedmode loading conditions, and the corresponding proportion varies with loading mix-ity. Void--growth processes are the failure mechanism in both predominately tensile-and shears--type fractures. The size and depth of dimples on the fracture surface varygreatly with thickness. Therefore, it is extraordinary necessary to take into accountthe thickness effect when a mixed mode fracture criterion is being established.

A MIXED MODE FRACTURE CRITERION BASED ON THE MAXIMUM TANGENTIAL STRESS IN BRITTLE INCLUSION

A closed-form solution for predicting the tangential stress of an inclusion located in mixed mode Ⅰ and Ⅱ crack tip field was developed based on the Eshelby equivalent inclusion theory. Then a mixed mode fracture criterion, including the fracture direction and the critical load, was established based on the maximum tangential stress in the inclusion for brittle inclusioninduced fracture materials. The proposed fracture criterion is a function of the inclusion fracture stress, its size and volume fraction, as well as the elastic constants of the inclusion and the matrix material. The present criterion will reduce to the conventional one as the inclusion having the same elastic behavior as the matrix material. The proposed solutions are in good agreement with detailed finite element analysis and measurement.

(Ⅰ+Ⅱ)MIXED MODE HYDROGEN INDUCED CRACKING

Hydrogen induced cracking(HIC)of 0.3% C,1% Cr,1% Mn,1% Si high strength steel has been studied under simple mode Ⅰ,mode Ⅱ and(Ⅰ+Ⅱ)mixed mode loading conditions.Af- ter being hydrogen-charged in IN H_2SO_4 solution,the material behaved hydrogen embrittlement in all the cases studied.The threshold K_(ⅡH)/K_(ⅡX) of HIC under mode Ⅱ load- ing was 0.27,which was nearly the same as that K(ⅠH)/K_(ⅠX)=0.29 under mode Ⅰ loading. While the thresholds of-HIC under(Ⅰ+Ⅱ)mixed mode loading were 0.36,0.41 and 0.37 cor- responding to the K_Ⅱ/K_Ⅰ ratio of 0.27,0.4 and O.81.The results show that simple mode Ⅰ or mode Ⅱ loading is more susceptible to hydrogen embrittlement than(Ⅰ+Ⅱ)mixed mode. For explaining the experimental results,the effects of triaxial stress as well as plastic deformation ahead of crack tip has been discussed.

Microscopic characteristics of different fracture modes of brittle rock

Three types of rock specimens, three-point bending specimen, anti-symmetric four-point bending specimen and direct shearing specimen, were used to achieve Mode I, Mode II and mixed mode I–II fracture, respectively. Microscopic characteristics of the three fracture modes of brittle rock were studied by SEM technique in order to analyze fracture behaviors and better understand fracture mechanisms of different fracture modes of brittle rock. Test results show that the microscopic characteristics of different fracture modes correspond to different fracture mechanisms. The surface of Mode I fracture has a great number of sparse and steep slip-steps with few tearing ridges and shows strong brittleness. In the surface of Mode II fracture there exist many tearing ridges and densely distributed parallel slip-steps and it is attributed to the action of shear stress. The co-action of tensile and shear stresses results in brittle cleavage planes mixed with streamline patterns and tearing ridges in the surface of mixed mode I–II fracture. The measured Mode II fracture toughness K II C and mixed mode I–II fracture toughness K mC are larger than Mode I fracture toughness K I C · K II C is about 3.5 times K I C, and KmC is about 1.2 times K I C.

混凝土Ⅰ-Ⅱ复合型裂缝扩展准则及扩展全过程的数值模拟

本文基于从试验中得出的混凝土Ⅰ-Ⅱ复合型裂缝起裂时的临界KⅠ-KⅡ曲线,提出了Ⅰ-Ⅱ复合型裂缝的扩展准则,即由外荷载在裂缝尖端产生的应力强度因子与虚拟裂缝黏聚力产生的应力强度因子的差大于或等于起裂时的临界KⅠ-KⅡ曲线时裂缝扩展,在此基础上采用有限元法对混凝土Ⅰ-Ⅱ复合型裂缝的起裂、稳定扩展及失稳扩展全过程进行了数值模拟,并计算了试件高度分别为2003、00、400、5006、00mm混凝土四点剪切梁的裂缝扩展路径、荷载-剪切位移曲线,数值模拟结果与试验结果吻合良好。研究表明,只要从试验中测得混凝土材料的Ⅰ-Ⅱ复合型裂缝起裂时的临界KⅠ-KⅡ曲线、抗拉强度及弹性模量,即可计算混凝土Ⅰ-Ⅱ复合型裂缝扩展全过程。

类岩石脆性材料非闭合裂纹的Ⅰ–Ⅱ压剪复合型断裂准则研究

实际工程中,结构体裂纹常处于拉剪和压剪复合受力状态,研究适合于复合型裂纹的断裂准则和裂纹扩展机理具有重要的理论意义和实用价值。以Ⅰ-Ⅱ复合型裂纹为研究对象,基于线弹性理论,在考虑裂纹几何特征及受力形式的基础上,系统介绍了裂纹应力强度因子(SIF)的理论解。提出了适用于Ⅱ型断裂的径向剪应力准则和双剪应力准则。对于Ⅰ-Ⅱ复合型裂纹,提出用等效Ⅰ、Ⅱ型SIF比值与Ⅰ、Ⅱ型断裂韧度比值的关系判定裂纹断裂类型,并分别选择适合于Ⅰ、Ⅱ型断裂的断裂准则,计算了裂纹断裂扩展理论角度。理论断裂角与预制非闭合裂纹类岩石脆性材料压剪断裂试验结果符合得较好。

数字图像相关法测定岩石Ⅰ-Ⅱ复合型裂纹应力强度因子

提出了一种通过数字图像相关方法测定岩石Ⅰ-Ⅱ复合型裂纹尖端位置和应力强度因子的试验方法。试验通过数字图像相关方法测定裂纹尖端区域位移场数据,将位移场数据带入极坐标系下位移场方程,计算裂纹尖端位置和应力强度因子。试验结果表明:采用该方法可以准确的测定岩石Ⅰ-Ⅱ复合型裂纹应力强度因子、裂纹尖端位置及裂纹扩展长度,解决了以往研究方法因不能准确测定裂纹尖端位置和扩展方向,而无法准确测定岩石应力强度因子的难题。

国产HTPB复合固体推进剂Ⅰ-Ⅱ型裂纹断裂性能实验研究

采用WDN-10KN材料实验机对含Ⅰ-Ⅱ复合型裂纹的HTPB复合固体推进剂进行了拉伸速率为2mm.min-1的单轴拉伸试验,用摄像机记录了推进剂裂纹扩展至断裂的整个过程。得到了六种不同裂纹倾斜角下的力-变形曲线及裂纹扩展开裂角和断裂载荷。与T断裂准则、S断裂准则和σθ断裂准则进行比较,结果表明推进剂裂纹扩展开裂角与T断裂准则的数值计算结果较为接近,说明可以借助于T断裂准则对推进剂裂纹扩展的初始开裂角进行初步的理论预测。

基于损伤理论的混凝土Ⅰ-Ⅱ复合型裂缝扩展角

基于混凝土断裂与损伤的基本理论,进行了Ⅰ-Ⅱ复合型裂缝扩展方向研究,研究结果表明:Ⅰ-Ⅱ复合型裂缝扩展趋势是随着缝端损伤场的变化而变化的。通过缝端损伤场及损伤梯度的计算,分析了Ⅰ-Ⅱ复合型裂缝从起裂至失稳断裂裂缝扩展方向的变化规律,得到了Ⅰ-Ⅱ复合型裂缝的起裂扩展角和失稳扩展角。将其与文献结果进行对比,对比结果表明:用损伤理论研究裂缝的扩展角是可行的。

混凝土 Ⅰ-Ⅱ 复合型断裂试验的试件形式及试验装置系统

在总结分析有关研究的基础上，对进行稳定混凝土断裂试验所需的条件及试验测量误差进行了分析，提出了适于混凝土Ⅰ－Ⅱ复合型断裂试验研究的试件及其加载测量系统，并分析了引起测量误差的原因．结果表明。

基于应变的Ⅰ/Ⅱ/Ⅲ复合型断裂准则

将已有的适用于平面断裂的最大周向应变(MTSN)准则,推广到适用于空间三维断裂的断裂准则.并具体讨论了Poisson(泊松)比对复合型断裂的面内断裂角与面外断裂角及断裂包络图的影响.Ⅰ/Ⅲ复合型断裂时,面外断裂角与Poisson比无关.Ⅱ/Ⅲ及Ⅰ/Ⅱ/Ⅲ复合型断裂条件下,面内断裂角随着Poisson比的增大而减小,面外断裂角随着Poisson比的增大而增大.在复合型断裂条件下,包络图均随着Poisson比增大而减小.且Poisson比对断裂包络图的影响大于面内断裂角,对面外断裂角影响最小.将本准则理论预测值与多组实验数据进行对比,预测值与实验值吻合较好,可知推广的MTSN准则能够较好地预测三维断裂.

Ⅰ-Ⅱ复合型裂缝应力强度因子和应变能释放率的关系

为了探究复合型裂缝的应力强度因子K和应变能释放率G的关系,基于最大应力准则,采用能量法对Ⅰ-Ⅱ复合型裂缝的扩展进行理论分析。根据单一型裂缝应力强度因子和应变能释放率的关系,推导出Ⅰ-Ⅱ复合型裂缝K与G的关系公式,利用Abaqus软件建立Ⅰ-Ⅱ复合型裂缝的有限元模型,计算Ⅰ-Ⅱ复合型裂缝的应力强度因子和应变能释放率,与推导公式的计算结果进行对比,二者误差仅为2.5%,验证了推导公式的合理性。

混凝土Ⅰ-Ⅱ复合型虚拟裂缝模型及断裂能研究

本文运用白光散斑技术分级测定了混凝土试样Ⅰ-Ⅱ复合型断裂的位移场,并对断裂过程区进行跟踪观察,探讨了断裂机理,据此建立起Ⅰ-Ⅱ复合型断裂虚拟裂纹模型.本文还以四点剪切和直偏缝三点弯曲两种试样,测录了Ⅰ-Ⅱ复合型荷载位移F～δ全曲线,并计算出不同复合状态下的断裂能G_F^(Ⅰ-Ⅱ).

Ⅰ-Ⅱ复合型裂缝断裂角剪滞方法

建立了混凝土等准脆性材料的Ⅰ-Ⅱ复合型裂缝在单向拉伸荷载作用下断裂角的修正剪滞模型,得到了与试验相吻合且优于传统S判据的断裂角．合理简化了复合型裂缝试样的力学边界条件,得到了裂缝体各剪滞子层位移分布函数的解析表达式．引用一种所谓的最大应力集中因子的概念,对Ⅰ-Ⅱ复合型裂缝前缘应力场进行了简化描述．得到了复合裂缝断裂角的解析解．根据斜裂缝体的应力分布概况,设置不同的子层分区,得到了更为细化的子层位移分布模式．通过对计算数据的分析,提出了合理的按应力场分区设置子层的剪滞分析模型,从而得到了更为精确的斜裂缝断裂角．新方法的计算结果与试验结果除个别外的相对误差小于4％,均小于S判据,显示算法的卓越性．

(Ⅰ+Ⅱ)复合型氢致开裂的研究

本文研究了30CrMnSiA高强钢在纯Ⅰ型、纯Ⅱ型和(Ⅰ+Ⅱ)复合型加载条件下的氢致开裂。实验表明,在1NH_2SO_4溶液中预充氢的试件在上述加载条件下均表现出氢致脆性。纯Ⅱ型氢致开裂门槛值K_(ⅡH)/K_(ⅡX)=0.27,与纯Ⅰ型门槛值K_(ⅠH)/K_(ⅠX)=0.29基本相同,而在K_Ⅱ/K_Ⅰ比值为0.27,0.4和0.81时,(Ⅰ+Ⅱ)复合型氢致开裂门槛值分别为0.36,0.41和0.37,表明纯Ⅰ型和纯Ⅱ型具有更高的氢脆敏感性。最后用自Ⅰ型加载向Ⅱ型过渡时,三轴张力和塑性变形程度这二个矛盾因素对氢致开裂的共同作用解释了上述实验结果。

Ⅰ-Ⅱ混合型裂纹的形状改变比能断裂准则的分析

利用形状改变比能分析了Ⅰ-Ⅱ混合型裂纹的开始角,形状改变比能断裂准则表明裂纹启裂方向与最小形状改变比能方向一致.该准则预测的Ⅰ-Ⅱ混合型裂纹开裂角和临界载荷与实验结果取得了较好的吻合.

Ⅰ-Ⅱ复合型裂纹J积分计算

采用3点弯试件,运用有限元分析软件ANSYS对复合型裂纹尖端J积分进行计算。通过应力强度因子KⅠ、KⅡ与J积分之间的关系对计算结果进行比较,验证了断裂参量之间的相互关联性。对不同网格划分情况下J积分的计算结果也进行了对比。结果表明,网格划分对计算结果没有影响,如果仅计算J积分值,裂纹尖端不必采用奇异单元划分网格。

双轴向载荷Ⅰ－Ⅱ复合型裂纹J积分断裂准则探讨

通过理论分析和双轴向断裂试验，对我国压力容器常用钢１６ＭｎＲ所制成的含中心穿透Ⅰ－Ⅱ复合型裂纹十字形试样的断裂规律进行了试验研究，探讨了Ⅰ－Ⅱ复合型裂纹Ｊ积分断裂准则。结果表明，不同的载荷比和裂纹倾角下Ⅰ－Ⅱ复合型裂纹的启裂Ｊｉ值接近。

基于表观断裂韧性的Ⅰ-Ⅱ型复合断裂准则分析

以Ⅰ-Ⅱ复合型裂纹结构为研究对象,对紧凑拉伸剪切试样(CTS)的剩余强度及开裂方向进行了理论分析及试验研究,推导出了仅与CTS结构加载角度相关的破坏载荷公式,并建立有限元模型(FEM),获取结构的表观断裂韧性值,试验验证了模型的可行性。通过对比不同断裂准则在开裂角、临界载荷及复合断裂韧度方面的工程适用性,表明基于von Mises应力的复合型断裂准则更有利于工程分析,为结构的承载能力评估提供了技术支持。

Ⅰ-Ⅱ复合型裂纹开裂角准则的评价

目前对Ⅰ-Ⅱ复合型裂纹开裂角的研究已有许多种不同的判定准则。文中将各种不同的判定准则与实验结果进行分析比较发现,李中华等根据钝裂纹尖端应力场解,将控制断裂的物理量最大切向应力σθmax定义在裂纹尖端裂纹面上,获得一个新的复合型裂纹断裂准则,该准则不但物理意义明确、表达简捷,而且较其他准则更符合可收集到的实验数据。从而得到工程中比较简单实用的断裂准则。