首页 | 本学科首页   官方微博 | 高级检索  
     检索      

考虑夹杂相互作用的复合陶瓷夹杂界面的断裂分析
引用本文:付云伟,张龙,倪新华,刘协权,于金凤,陈诚.考虑夹杂相互作用的复合陶瓷夹杂界面的断裂分析[J].力学学报,2016,48(1):154-162.
作者姓名:付云伟  张龙  倪新华  刘协权  于金凤  陈诚
作者单位:1. 军械工程学院火炮工程系, 石家庄 050003; 2. 军械工程学院车辆与电气工程系, 石家庄 050003; 3. 军械工程学院基础部, 石家庄 050003; 4. 中国人民解放军78638部队, 什邡 618400
基金项目:国家自然科学基金资助项目(11272355)
摘    要:复合材料中夹杂含量较高时,夹杂间的相互作用能显著改变材料细观应力应变场分布,基体和夹杂中的平均应力应变水平也会发生较大变化,导致复合材料强度等力学性能发生显著变化.为修正单一夹杂模型运用在实际材料中的误差,基于相互作用直推估计法,建立一种考虑含夹杂相互作用的夹杂界面裂纹开裂模型.首先根据相互作用直推估计法,得到残余应力和外载应力共同作用下夹杂中的平均应力,再计算无限大基体中相同的夹杂达到相同应力场时的等效加载应力,将此加载应力作为含界面裂纹夹杂的等效应力边界条件,在此边界条件下求得界面裂纹尖端的应力强度因子,进而得到界面裂纹开裂的极限加载条件,并分析了夹杂弹性性能、含量、热残余应力、夹杂尺寸等因素对界面裂纹开裂条件的影响.结果表明,方法能够有效修正单夹杂模型运用在实际材料中的误差,较大的残余应力对界面裂纹开裂有重要的影响,夹杂刚度的影响并非单调且比较复杂;在残余应力较小时,降低柔性夹杂刚度或者增大刚性夹杂刚度都有利于提高材料强度;扩大夹杂尺寸将导致裂纹开裂极限应力显著降低,从而降低材料强度.

关 键 词:圆形夹杂  界面裂纹  相互作用  相互作用直推估计法  开裂应力
收稿时间:2014-12-10
修稿时间:2015-10-21

INTERFACE CRACKING ANALYSIS WITH INCLUSIONS INTERACTION IN COMPOSITE CERAMIC
Fu Yunwei,Zhang Long,Ni Xinhuay,Liu Xiequan,Yu Jinfeng,Chen Cheng.INTERFACE CRACKING ANALYSIS WITH INCLUSIONS INTERACTION IN COMPOSITE CERAMIC[J].chinese journal of theoretical and applied mechanics,2016,48(1):154-162.
Authors:Fu Yunwei  Zhang Long  Ni Xinhuay  Liu Xiequan  Yu Jinfeng  Chen Cheng
Institution:1. Department of Artillery Engineering, Ordnance Engineering College, Shijiazhuang 050003, China; 2. Department of Vehicle and Electric Engineering, Ordnance Engineering College, Shijiazhuang 050003, China; 3. Department of Basic Course, Ordnance Engineering College, Shijiazhuang 050003, China; 4. Unit No.78638 of PLA, Shifang 618400, China
Abstract:Micro strain and stress field and the average field is significantly influenced by the interaction of inclusions of high volume fraction, and the composite mechanical properties changes a lot by the introduced inclusions. To reduce the error of using the theoretical model with single inclusion in real multi-inclusion-material property prediction, an inclusion interface cracking model is established based on the interaction direct derivative (IDD) estimate. Average e ective stress field is obtained under applied loading and residual stress based on the IDD estimate, then the stress intensity factor (SIF) of interface arc-crack around circular inclusion under the stress boundary condition is calculated. The critical applied stress is evaluated according to the e ective stress field and the interface arc-crack SIF, and the influence of inclusion elastic modulus, volume fraction, residual stress, and inclusion size are analysed. The result indicates that the method is e ective. Residual stress has remarkable influence to interface cracking; the critical applied stress is not monotonic and complicated with the inclusion sti ness variation when the residual stress is large, while the critical applied stress is increasing with the soft inclusion decreasing the sti ness and the sti inclusion increasing the sti ness when the residual stress is small; large size inclusion decreases the critical applied stress and detrimental to composite strength.
Keywords:circular inclusion  interface crack  interaction  the interaction direct derivative estimate  crack stress
本文献已被 CNKI 万方数据 等数据库收录!
点击此处可从《力学学报》浏览原始摘要信息
点击此处可从《力学学报》下载免费的PDF全文
设为首页 | 免责声明 | 关于勤云 | 加入收藏

Copyright©北京勤云科技发展有限公司  京ICP备09084417号