含边界和损伤因素的纺织复合材料细观胞元模型

纺织复合材料的细观力学分析通常以胞元模型为基础,胞元边界条件的合理施加是获得精确分析结果的关键之一。本文以平面机织复合材料为例,讨论了细观胞元的选取和周期边界条件的施加方法,在此基础上建立了二维细观有限元模型,通过与全厚度模型分析结果的比较,研究了周期胞元模型的合理性,特别是边界效应和局部损伤等非周期因素对分析结果的影响,给出了这些因素下胞元边界条件的处理方法。     

M46J高模量碳纤维预浸QY8911纤维束性能研究

以航空发动机应用为背景，研究了M46J／QY8911缠绕复合材料的预浸纱制备方法及性能，根据M46J特性，对现有的GB3326中纤维束力学性能测试试样的加强方式进行了改进，制作了M46J浸渍QY8911树脂的纤维束试样并测试其力学性能，同时与M46J浸渍环氧树脂的纤维束的力学性能进行比较，研究表明，不同树脂特性，不同固化工艺以及制造中所施加的张力都会影响到纤维束的纤维利用率。     

CuAl2／Al复合材料的固相反应合成技术及与Al液的接触反应研究

研究了Ａｌ，Ｃｕ在真空状态下的纯固相接触反应情况，试验表明，Ａｌ粉、Ｃｕ粉在６００℃，保温６ｈ时，两者以完全发生反生成ＣｕＡｌ２（θ相），生成的θ相沿铝基体组织晶界分布并在结晶过程中具有择优取向特性，形成仅含沿晶界方向的主干与垂直于晶界的二次晶轴的树枝晶形貌。     

复合材料固化应力模型

本文建立了描述复合材料固化应力史的综合模型。在本模型中考虑了化学收缩对残余应力史的贡献,并考虑了以玻璃化转变区为应力释放区的应力松弛过程。整个模型由四部分组成:描述温度场的模型、物理力学参数的模型、描述细观纵向残余应力史的模型、描述层合固化应力史的模型。     

复合材料薄壁加筋抛物面天线仿真与优化

采用Patran/Nastran有限元软件对复合材料薄壁加筋抛物面天线进行了建模和仿真分析。重点分析了反射面铺层方式、加筋结构形式以及加强筋铺层对抛物面天线基频的影响。分析结果表明:采用[0/45/-45/90]s铺层形式的反射面基频最高;增加径向和环向筋可大幅提高天线基频,其中加筋结构采用[0/30/90/-30]s铺层可进一步提高天线基频。通过有限元分析确定了基频最佳的复合材料抛物面天线结构,为制备薄壁加筋抛物面天线提供了指导。     

基于一种新的均匀化实施方法的FRP刚度预测

基于一种新的渐近均匀化(AH)实施方法,预测并讨论了单向纤维增强复合材料(FRP)的宏观等效弹性性能及纤维排列方式对等效力学性能的影响。该方法方便地将有限元分析(FEA)软件作为一个工具箱使用,只需在单胞上施加简单位移周期边界条件开展静力学分析,即可经过简单计算得到等效弹性常数,相比传统均匀化实施方法显著降低了实施难度并简化了计算过程。通过对比不同数值方法的结果验证了该方法的有效性和精确性。数值结果表明:六边形排列下单向纤维增强复合材料呈现横观各向同性,而正方形排列下则呈现宏观正交各向异性,经过刚度平均化过程可得到横观各向异性材料性质,纤维体积含量对两种排列方式下材料等效弹性模量影响显著但有所差别。     

大曲率复合材料结构的缺陷特征与超声检测

采用超声回波法对大曲率碳纤维增强树脂基复合材料零件进行超声A 扫描，并对缺陷进行定位。结合缺陷区域和非缺陷区域的细观形貌金相图、宏观表面状态以及厚度测量结果的对比分析，讨论了缺陷形态与其回波波形特征的对应关系，以及缺陷可能的形成原因。结果表明，缺陷在细观尺度上呈现多处分层、气孔和孔隙密集缺陷，在宏观尺度上表现为零件表面贫胶与厚度增厚。缺陷的性质与超声A扫描的检测结果相吻合，缺陷的位置集中在零件大曲率部位，其形成原因与复合材料制造工艺密切相关。     

A novel surrogate modeling strategy of the mechanical properties of 3D braided composites

In this paper, a surrogate-based modeling methodology is developed and presented to predict the elastic properties of three dimensional (3D) four-directional braided composites. Using this approach, the prediction process becomes feasible with only a limited number of training points. The surrogate models constructed using Finite Element (FE) method and Diffuse Approximation, reduce the computational time and cost for preparing experimental samples. In the FE model, multiscale method is applied to couple the computations of elastic properties at microscale and mesoscale. Subsequently, a parametric study is performed to analyze the effects of the three design parameters on the elastic properties. Satisfactory results are obtained via the surrogate-based modeling predictions, which are compared with the experimental measurements. Moreover, the predictions obtained from surrogate models concur well with the FE predictions. This study orients a new direction for predicting the mechanical properties based on surrogate models which can effectively reduce the sample preparation cost and computational efforts.     

Influence of TiB2 particles on machinability and machining parameter optimization of TiB2/Al MMCs

In situ formed TiB₂ particle reinforced aluminum matrix composites (TiB₂/Al MMCs) have some extraordinary properties which make them be a promising material for high performance aero-engine blade. Due to the influence of TiB₂ particles, the machinability is still a problem which restricts the application of TiB₂/Al MMCs. In order to meet the industrial requirements, the influence of TiB₂ particles on the machinability of TiB₂/Al MMCs was investigated experimentally. Moreover, the optimal machining conditions for this kind of MMCs were investigated in this study. The major conclusions are: (1) the machining force of TiB₂/Al MMCs is bigger than that of non-reinforced alloy and mainly controlled by feed rate; (2) the residual stress of TiB₂/Al MMCs is compressive while that of non-reinforced alloy is nearly neutral; (3) the surface roughness of TiB₂/Al MMCs is smaller than that of non-reinforced alloy under the same cutting speed, but reverse result was observed when the feed rate increased; (4) a multi-objective optimization model for surface roughness and material removal rate (MRR) was established, and a set of optimal parameter combinations of the machining was obtained. The results show a great difference from SiC particle reinforced MMCs and provide a useful guide for a better control of machining process of this material.     

纤维增韧陶瓷基复合材料的比例极限应力与残余热应力关系

从细观力学角度分析并建立了纤维增韧陶瓷基复合材料从制备温度冷却到室温过程中产生的残余热应力与复合材料的比例极限应力的关系模型。该模型表明,减少复合材料的残余热应力或提高复合材料的纤维与基体的模量比,均可提高复合材料的比例极限应力。通过单调拉伸实验测试了先驱体浸渍裂解法(PIP)制备的2D SiC/SiC复合材料的比例极限应力,并采用文中建立的比例极限应力与残余热应力关系模型,计算出复合材料SiC基体的残余热应力为-19.5 MPa。分析表明,该结果是合理的。此外,引用了公开文献报道的5种复合材料体系数据,用于验证文中所建立的比例极限应力与残余热应力关系模型的适应性和可靠性,计算结果与实验结果最大误差为18.6%,表明该模型具有较好的适应性和可靠性,可为纤维增韧陶瓷基复合材料的研究提供新思路。