边界条件对复合材料层合板准静态压痕损伤的影响

在实际的服役过程中,飞机用复合材料层合板通过四边铆接的方式与飞机金属框架进行连接,其受力时的边界条件为四边固支。以实际应用背景为基础,分别从分层损伤扩展模式、接触力、凹坑深度、损伤宽度四个方面系统地比较了四边固支和四边简支两种边界条件下,复合材料层合板准静态压痕损伤的区别。结果表明以上四种变量在两种边界条件下均存在明显差异,可为基于实际应用的复合材料准静态压痕损伤研究提供实验依据。     

玻璃纤维增强复合材料的损伤分析

本文对玻璃纤维增强复合材料层合板进行了拉、剪多向应力本构关系的实验研究,成功地用软x射线照相观察到材料内部微裂纹沿纤维方向近似均匀分布,并沿裂纹面扩展至破坏的损伤形貌,同时结合声发射技术等监测其扩展规律。在此基础上建立了基于微观机制的微裂纹损伤模型,预测材料的损伤非线性本构关系和破坏,以及实验观察到的一些复合材料特有的损伤现象,理论预测结果与实验值吻合。     

复合材料的弹性常数与损伤的直接测试

本文将复合材料细观力学和复合材料微裂纹损伤理论与直接测试方法结合起来,在一次加载条件下直接测得复合材料结构件的弹性常数和损伤变量随外载的变化规律,从而可避免直接测试方法的多次加载的困难。由碳纤维／环氧复合材料圆筒壳的轴压实验的直接测试所得结果比较合理,表明该方法是合理可靠的,特别是在加载条件下直接测得复合材料结构件的损伤发展规律之后,可将复合材料微裂纹损伤理论直接用于工程结构件的动态损伤监测。     

基于响应面法的复合材料层合板平面应力强度可靠性分析

针对处于平面应力状态下的复合材料层合板，考虑其材料参数、强度参数、几何尺寸以及承受载荷等随机因素，用分支限界法识别结构系统的各重要失效序列，应用响应面法对某具体层合板的各失效事件进行计算，进而计算出整个系统的失效概率，并且利用MATLAB程序以及ANSYS中的APDL语言编写了JC法计算程序。计算结果表明，一般情况下层合板首先出现基体损伤失效，然后才会出现纤维断裂失效。这一结果与一些文献中的试验结果相一致，表明这种概率分析方法可以应用于实际复合材料层合板结构的可靠性分析。     

复合材料层合板疲劳寿命形状参数与门槛值分析方法

复合材料性能具有较大的分散性,在表征复合材料疲劳寿命时,必须考虑分散性的影响。以M21C复合材料开孔层合板为研究对象,采用Sendeckyj等效静强度模型和随机变量函数的概率分布方法推导了复合材料层合板疲劳寿命形状参数和剩余强度形状参数的关系,通过试验和统计的方法获得了M21C复合材料开孔层合板的疲劳寿命形状参数和疲劳门槛值,对载荷放大系数以及低载截除水平的确定提供了数据支持。     

集成于碳纤维复合材料的fsFBG响应特性研究

针对航空航天碳纤维复合材料结构健康监测需求,研究了飞秒激光逐点直写光纤光栅传感器(fsFBG)和碳纤维复合材料集成时的传感特性。在碳纤维复合材料层合板表面及层间布置fsFBG,对碳纤维复合材料层合板进行静态载荷和低速冲击载荷加载实验,系统分析了表面和不同层间fsFBG对载荷响应的敏感性和差异性,得到了fsFBG中心波长偏移量与加载距离和加载角度的对应关系。实验表明,表面粘贴的fsFBG对动静载荷的敏感度更高,在动静态载荷作用下,fsFBG中心波长偏移量随加载载荷的增大呈线性递增,而随加载距离的增加而逐渐减小;fsFBG具有较好的载荷-方向敏感特性,传感器的响应灵敏度随加载夹角增大逐渐提高。     

开孔复合材料层合板的拉伸强度和失效模式分析

为研究纤维编织工艺、铺层角度和孔径大小对开孔复合材料层合板拉伸强度和失效模式的影响规律,选用正交平纹玻纤层合板（WFL）和单向玻纤层合板（UFL）制作0°和45°铺层开孔拉伸试件,随后进行了试验研究;采用 Abaqus 建立基于二维 Hashion 失效准则的渐进损伤仿真模型,并对试验结果进行了对比,分析了试件的损伤机理。研究结果表明：层合板强度随开孔增大而减小,并且这种变化率随孔径增大而增大,45°铺层的层合板的变化率小于0°铺层,WFL 小于 UFL;WFL 的破坏以纤维断裂为主,裂纹垂直于纤维方向,UFL 以基体开裂为主,裂纹沿纤维方向,孔径则对破坏模式无明显影响;0°铺层 WFL 的破坏是由纤维拉伸失效导致,45°的则由纤维拉伸失效和基体拉伸剪切失效共同导致,0°铺层 UFL 由基体压缩失效导致,45°的则由基体拉伸剪切失效导致;拉伸强度的仿真与试验结果最大误差为14．1％,由此验证了仿真计算方法的有效性。     

冲击波载荷作用下固支正交各向异性薄板挠度特性分析

根据能量原理,采用层合板理论和薄板大变形理论,对四边固支的矩形正交铺层的纤维增强复合材料薄板在爆炸冲击波作用下的弹性大变形进行理论分析,得到了层合板的最大挠度计算公式。有限元数值模拟计算表明,理论计算结果与有限元数值模拟的结果吻合较好,因此该方法可用来对复合材料板在弹性范围内的最大挠度进行预测,同时认为根据薄板的最大挠度,可以计算板的应力(应变)分布和复合材料板失效时的爆炸载荷。     

复合材料层合结构层向理论及应用进展

层向理论是由Reddy提出来的一种用于精确分析复合材料层合结构的三维板壳分析理论。由于不引入任何的变形和应力假设条件,因此相较于传统的等效单层板理论,层向理论在分析大厚度复合材料层合板壳结构的静动态响应及其局部层间效应时具有较大的优势。系统地综述了层向理论近年来的研究进展、数值解法及其应用情况。具体包括:层向理论的基本原理及发展现状、基于层向理论的有限元方法及改进模型、层向理论在复合材料层合结构静动态响应及含损伤问题领域的应用等。并对该理论可进一步拓展的研究方向进行了展望。     

复合材料层合结构的非线性传热分析

基于一阶热层合理论,考虑材料非线性的影响,建立了复合材料层合结构非线性传热分析的热层合理论及其有限元方程.通过数值算例研究了材料非线性对反对称复合材料层合板瞬态温度场的影响.     

Damage visualization and deformation measurement in glass laminates during projectile penetration

Transparent armor consists of glass-polymer laminates in most cases. The formation and propagation of damage in the different glass layers has a strong influence on the ballistic resistance of such laminates. In order to clarify the course of events during projectile penetration, an experimental technique was developed, which allows visualizing the onset and propagation of damage in each single layer of the laminate. A telecentric objective lens was used together with a microsecond video camera that allows recording 100 frames at a maximum rate of 1 MHz in a backlit photography set-up. With this technique, the damage evolution could be visualized in glass laminates consisting of four glass layers with lateral dimensions 500 mm × 500 mm. Damage evolution was recorded during penetration of 7.62 mm AP projectiles with tungsten carbide core and a total mass of 11.1 g in the impact velocity range from 800 to 880 m/s. In order to measure the deformation of single glass plates within the laminates, a piece of reflecting tape was attached to the corresponding glass plate, and photonic Doppler velocimetry (PDV) was applied. With the photonic Doppler velocimeter, an infrared laser is used to illuminate an object to be measured and the Doppler-shifted light is superimposed to a reference light beam at the detector. The simultaneous visualization and PDV measurement of the glass deformation allow determining the deformation at the time of the onset of fracture. The analysis of the experimental data was supported by numerical simulations, using the AUTODYN commercial hydro-code.     

Crashworthiness performance of hybrid kenaf/glass fiber reinforced epoxy tube on winding orientation effect under quasi-static compression load

This research was aimed to study the effect winding orientation on the crashworthiness performance of hybrid tube. The specimens tested under quasi-static compression load involve of three winding parameters (θ = 30°, 45° and 70°) of hybrid kenaf/glass fiber reinforced epoxy and glass fiber reinforced epoxy as contrast specimen. The automated filament winding technique has been used in fabrication of hybrid and non-hybrid composite tube and crashworthiness performance was investigated experimentally. The effects of winding orientation on energy absorption capabilities and crashworthiness characteristic were investigated through quasi-static compression load and the result are compared with the glass fiber composite tube to justify the capability of hybrid natural/synthetic as energy absorption application. Hybridized samples proved to enhancing the progressive crushing capability as combination of local buckling, delaminate and brittle fracturing as progressive crushing modes.In the view of winding orientation aspect, the results of high winding orientation of hybrid composite tube elevated the crush load efficiency, specific energy absorption and energy absorption capability compared to glass composite tube (GFRP). The hybrid kenaf/glass composite tube with high winding orientation showed the best winding orientation to enhance the energy absorber characteristics as energy absorption application.     

Investigation of the mechanical and ballistic properties of hybrid carbon/ aramid woven laminates

High-performance ballistic fibers, such as aramid fiber and ultra-high-molecular-weight polyethylene (UHMWPE), are commonly used in anti-ballistic structures due to their low density, high tensile strength and high specific modulus. However, their low modulus in the thickness direction and insufficient shear strength limits their application in certain ballistic structure. In contrast, carbon fiber reinforced epoxy resin matrix composites (CFRP) have the characteristics of high modulus in the thickness direction and high shear resistance. However, carbon fibers are rarely used and applied for protection purposes. A hybridization with aramid fiber reinforced epoxy resin matrix composites (AFRP) and CFRP has the potential to improve the stiffness and the ballistic property of the typical ballistic fiber composites. The hybrid effects on the flexural property and ballistic performance of the hybrid CFRP/AFRP laminates were investigated. Through conducting mechanical property tests and ballistic tests, two sets of reliable simulation parameters for AFRP and CFRP were established using LS-DYNA software, respectively. The experimental results suggested that by increasing the content of CFRP that the flexural properties of hybrid CFRP/AFRP laminates were enhanced. The ballistic tests’ results and the simulation illustrated that the specific energy absorption by the perforation method of CFRP achieved 77.7% of AFRP. When CFRP was on the striking face, the shear resistance of the laminates and the resistance force to the projectiles was promoted at the initial penetration stage. The proportion of fiber tensile failures in the AFRP layers was also enhanced with the addition of CFRP during the penetration process. These improvements resulted in the ballistic performance of hybrid CFRP/AFRP laminates was better than AFRP when the CFRP content was 20 wt% and 30 wt%.     

复合材料修补金属裂损结构吸湿老化的试验与有限元分析

暴露在湿热环境中的复合材料修补金属裂损结构易吸湿老化,导致该结构性能下降,服役寿命缩短。为研究吸湿性对复合材料修补金属裂损结构修补效果和耐久性的影响,利用试验方法分析了吸湿性对复合材料胶补金属裂损结构及胶黏剂力学性能的影响;利用有限元方法评估了吸湿性对复合材料胶补金属裂损结构试验件修补效果和耐久性的影响。研究结果表明:吸湿后含穿透双边裂纹铝合金板玻璃纤维单面胶补试验件的疲劳裂纹扩展寿命和极限载荷的平均值分别下降为吸湿前的71%和90%;吸湿造成拉伸条件下复合材料胶补金属裂损结构胶层失效模式由内聚破坏为主转变为界面破坏为主;在"湿-热"老化30天后,E44/聚酰胺环氧树脂胶黏剂试验件吸水饱和,弹性模量下降为未老化前的40%,塑性应变超过了总应变的25%;有限元分析发现胶层损伤受吸湿影响明显,吸湿性加速了胶层损伤,且裂纹长度越长,加速作用越明显;同时吸湿使得裂纹尖端的J积分值急剧增大,导致修补结构的疲劳裂纹扩展寿命缩短,裂纹长度越长,吸湿性对于复合材料胶接修补效果的危害越严重。     

碳纤维增强聚合物基复合材料频率选择表面的电磁传输特性（复合材料专栏投稿）*

为了改善采用金属频率选择表面（Frequency Selective Surface，FSS）制备的天线罩中存在的热残余应力和弱粘接界面等问题，本文采用与聚合物基复合材料罩壁结构相容性好的碳纤维增强聚合物基复合材料制备FSS，利用自由空间法对试样的电磁传输性能进行测试，并采用数值分析模型对碳纤维复合材料FSS的电磁传输机制和电磁传输影响因子进行分析。结果表明：碳纤维复合材料FSS具有频率选择功能，但谐振频率处的电磁传输损耗较大；通过改变复合材料FSS的单元缝隙率、厚度、电导率以及介电常数可以实现对其电磁传输性能的调节。     

Investigation of normal,lateral, and oblique impact of microscale projectiles into unidirectional glass/epoxy composites

Spacesuits and spacecraft must endure high velocity impacts from micrometeoroids. This work considers the impact of 100 μm diameter projectiles into composite targets at velocities from 0.5 km/s to 2 km/s. This work begins by presenting an energy-based theoretical model relating depth of penetration (DoP) and impact force to impact velocity, characteristic time, and threshold velocity and force. Next, this work compares numerical simulations of normal impact on composites to the theoretical model. Numerical simulations are conducted with LS-DYNA and the well-known composite model, MAT-162. The numerical models consider unidirectional S2-glass fiber reinforced SC-15 epoxy composite laminates. The numerical model shows good correlation with the theoretical model. The numerical model also investigates lateral impact, parallel to the fiber direction, and oblique impact at angles from 30° to 82.5°. This work decomposes oblique impact into normal and lateral components, and compares them with normal and lateral impact results. The results show good correlation of the normal component of oblique results with the theoretical model. This numerical and theoretical study focuses on DoP, velocity, and penetration resistance force as functions of time. The theoretical model and numerical simulations are used to determine new DoP parameters: characteristic time of depth of penetration and threshold impact velocity. These models are a first step in developing the capability to predict DoP for oblique, microscale, high-speed impact on composite materials.     

Low velocity impact studies of E-glass/epoxy composite laminates at different thicknesses and temperatures

Low velocity impact experiments were carried out on E-glass/epoxy composite laminates having varying thicknesses at sub zero and elevated temperatures using hemi spherical steel impactor of 16 mm diameter with impact energies in the rage of 50–150 J. The performance of the laminates was assessed in terms of energy absorption, maximum displacement, peak force and failure behaviour. Results indicated that the effect of temperature on energy absorption of the laminate is negligible although the laminates are embrittling at sub zero temperatures. However it has influence on failure behaviour and displacement. Peak force has increased linearly with increase in laminate thickness from 5 to 10 mm. However it got reduced by 25% when temperature was increased from −20 °C to 100 °C. Based on experimental results, laminate perforation energies were predicted using curve fitting equations. Statistical analysis was carried out using Taguchi method to identify the global effects of various parameters on laminate performance and confirmed that the laminate thickness has significant influence as compared to temperature, for the studied range.     

B4C／Al复合板中应力波行为分析（Ⅱ）

在已建立的应力波传播模型和研究弹、板间作用力所获结果的基础上，为分析复合板应力的变化，对复合板弹板碰撞承受的应力进行了简化处理，根据应力波传播特性，确定了复合板内能量集中区域，研究了应力波在复合板巾的传播和能耗，并讨论了应力波对陶瓷的作用。通过近似计算，发现烧蚀消耗的弹丸动能较大，在复合板中，Al板的塑性变形吸收了19％的弹丸动能。