基体合金相组成对硼化物增强镁锂基复合材料组织和性能的影响

采用原位合成法制备了硼化物增强Mg-Li基复合材料。针对基体为Mg-14Li-1Al-1Y的复合材料力学性能仍不能满足工业应用需求的缺陷,以Mg-9Li-1Al-1Y镁锂合金为基体制备了硼化物增强镁锂基复合材料(其成分为(Mg-9Li-1Al-1Y)-6B_4C)。研究了Li含量对基体合金和复合材料组织和性能的影响。试验结果表明:合金Mg-9Li-1Al-1Y与合金Mg-14Li-1Al-1Y相比,其双相区组织晶粒更加细小,各力学性能均有所提高。(Mg-9Li-1Al-1Y)-6B_4C复合材料与Mg-9Li-1Al-1Y合金相比,硬度提高了66%,抗拉强度提高了31.33%,伸长率降低了15.5%。(Mg-9Li-1Al-1Y)-6B_4C与(Mg-14Li-1Al-1Y)-6B_4C相比,屈服强度降低了15.4%,硬度提高了29.3%,抗拉强度和伸长率基本保持不变。以上试验结果表明:随着Li含量的降低复合材料的力学性能没有得到提高,没有实现基体合金强度增加从而相应复合材料强度增加的试验预期,说明相比镁锂基复合材料强化机制中第二相强化与细晶强化的作用,基体强化作用较弱难以体现。     

固体冲压发动机喷管用C/C-SiC复合材料

采用"化学气相渗透+先驱体浸渍裂解"(CVI+PIP)混合工艺制备固体冲压发动机用C/C-SiC复合材料喷管内层,综合考查复合材料的微观结构、弯曲性能和抗烧蚀性能以及固冲发动机C/C-SiC喷管内层水压和点火实验。结果表明:复合材料的弯曲强度达到197 MPa,且断裂破坏行为呈现典型的韧性模式;复合材料具有优异的抗氧化烧蚀性能,氧化烧蚀200 s后线烧蚀率仅为0.0063 mm·s-1;研制的C/C-SiC复合材料构件的水压爆破压强为6.5 MPa,表明构件具有良好的整体承载能力;C/C-SiC复合材料喷管内层高温综合性能通过了固体冲压发动机点火实验考核。     

Theoretical aspects of selecting repeated unit cell model in micromechanical analysis using displacement-based finite element method

Repeated Unit Cell(RUC)is a useful tool in micromechanical analysis of composites using Displacement-based Finite Element(DFE)method,and merely applying Periodic Displacement Boundary Conditions(PDBCs)to RUC is almost a standard practice to conduct such analysis.Two basic questions arising from this practice are whether Periodic Traction Boundary Conditions(PTBCs,also known as traction continuity conditions)are guaranteed and whether the solution is independent of selection of RUCs.This paper presents the theoretical aspects to tackle these questions,which unify the strong form,weak form and DFE method of the micromechanical problem together.Specifically,the solution’s independence of selection of RUCs is dealt with on the strong form side,PTBCs are derived from the weak form as natural boundary conditions,and the validity of merely applying PDBCs in micromechanical Finite Element(FE)analysis is proved by referring to its intrinsic connection to the strong form and weak form.Key points in the theoretical aspects are demonstrated by illustrative examples,and the merits of setting micromechanical FE analysis under the background of a clear theoretical framework are highlighted in the efficient selection of RUCs for Uni Directional(UD)fiber-reinforced composites.     

先进复合材料国防科技重点实验室的航空树脂基复合材料研发进展

归纳先进复合材料国防科技重点实验室在航空先进树脂基复合材料方面的应用和研究进展.研制出超薄热塑性无纺织物层间增韧技术以实现提高复合材料的CAI性能.设计出的多夹层结构具有多层吸收拓展频带的作用,使多夹层隐身复合材料的吸收频宽达1 ～ 18GHz.高韧性树脂基复合材料和耐高温复合材料技术得到发展,并形成预浸料-热压灌成型、液态成型和自动化制造技术体系.发展复合材料固化、树脂流动、固化变形等模拟优化技术,并建立复合材料数据库技术.建立先进复合材料国防科技重点实验室可在支撑航空装备研制,在航空复合材料创新引领、体系主导、基础支撑和保障应用方面发挥作用.     

Effect of interface debonding on matrix multicracking evolution of fiber-reinfroced ceramic-matrix composites

An analytical methodology was developed to investigate the effect of fiber/matrix interface debonding on matrix multicracking evolution of fiber-reinforced CMCs(ceramic-matrix composites). The Budiansky-Hutchinson-Evans shear-lag model was adopted to analyse the micro-stress field of the damaged composites. The critical matrix strain energy criterion, which presupposes the existence of an ultimate or critical matrix strain energy with matrix, was obtained to simulate the matrix multicracking evolution of CMCs. With the increase of the applied stress, the matrix multicracking and fiber/matrix interface debonding occurred to dissipate the additional energy entered into the composites. The fiber/matrix interface debonded length under matrix multicracking evolution was obtained by treating the interface debonding as a particular crack propagation problem. The conditions for no-debonding and debonding during the evolution of matrix multicracking were discussed in terms of two interfacial properties, i.e., the interface shear stress and interface debonded toughness. When the fiber/matrix interface was bonded, the matrix multicracking evolution was much more intense compared with the interface debonding; when the fiber/matrix interface was debonded, the matrix crack density increased with the increasing of interface shear stress and interface debonded energy. The theoretical results were compared with experimental data of unidirectional SiC/CAS(calcium alumina silicate), SiC/CAS-Ⅱ and SiC/borosilicate composites.      

Prediction of cutting forces in ball-end milling of 2.5D C/C composites

Machining of carbon/carbon (C/C) composite materials is difficult to carry out due to its high specific stiffness, brittleness, anisotropic, non-homogeneous and low thermal conductivity, which can result in tear, burr, poor surface quality and rapid wear of cutters. Accurate and fast pre-diction of cutting forces is important for milling C/C composite materials with high quality. This paper presents an alternative cutting force model involving the influences of the directions of fiber. Based on the calculated and experimental results, the cutting forces’ coefficients of 2.5D C/C com-posites are evaluated using multiple linear regression method. Verification experiment has been car-ried out through a group of orthogonal tests. Results indicate that the proposed model is reliable and can be used to predict the cutting forces in ball-end milling of 2.5D C/C composites.     

固体火箭发动机壳体复合裙RTM成型技术

树脂传递模塑工艺(RTM)可实现复合材料承力构件高表面质量净尺寸成型。以A配方为树脂基体、3K缎纹碳布为增强材料,采用RTM工艺制备了固体火箭发动机壳体复合裙。分析了A配方的RTM工艺特性及树脂浇铸体性能,介绍了复合裙注射模具和注射设备,讨论了RTM工艺参数及复合裙材料性能。结果表明:RTM复合裙纤维体积分数达54. 5%,联合载荷(轴压+弯矩)条件下轴压达748 kN,弯矩达94 N·m;纯轴压载荷达1 062 kN,纯弯矩载荷达143. 1 N·m,壳体复合裙整体强度高,满足设计和使用要求。     

高效湿法缠绕用环氧树脂配方及其复合材料性能

针对高质固体火箭发动机壳体高效的生产要求对不同官能度环氧树脂复配体系的工艺性进行研究,重点开展了多官能团环氧树脂复配体系配方设计及力学性能研究,分别采用DSC(差示扫描分析)、黏度测试进行固化特征温度、固化反应动力学及工艺适用期研究,并最终制备单向层合板及NOL(the Naval Ordnance Laboratory)环进行复合材料性能的测试分析。研究结果表明:三官能度复配的环氧树脂能满足高效湿法缠绕要求。当三官能度的TDE-85质量分数为25%时,综合性能达到最优,适用期仅为120 min,拉伸强度为973 MPa,弯曲强度为115 MPa,玻璃化转变温度高达466 K,较最低值分别提高363%、159%、258%。该树脂体系与纤维匹配性好,复合材料性能优良,NOL环拉伸强度与层间剪切强度分别为256 GPa、744 MPa,纤维强度利用率达766%,适用于固体火箭发动机湿法缠绕成形。     

纤维增强涡轮轴结构失效模式分析方法及试验验证

针对连续纤维增强复合材料涡轮轴结构失效模式分析问题,基于宏-细观力学跨尺度分析方法,建立细观力学代表性体积元(RVE)模型,通过编程模拟实现模型的周期性边界条件,计算纤维增强复合材料应力响应,将其均值应力转化为真实应力,确定失效包线。建立连续纤维增强轴结构力学模型,计算轴结构在扭转载荷下的应力响应。通过复合材料层合板主偏轴关系应力转化,将危险单元各方向宏观应力响应计算结果转化到细观力学RVE模型上,即为细观力学RVE模型受载情况。结合细观力学失效边界确定复合材料轴结构危险位置失效模式,当扭转载荷达到5 000～5 500 N·m之间,复合材料最外层即层6(+45°)首先达到基体拉伸失效载荷。开展复合材料轴结构失效模式试验,在扭转载荷达到6 000 N·m时,声发射信号相互叠加,大部分均为中频信号,中频信号多为基体、界面开裂信号。与模拟仿真计算结果对比分析,验证连续纤维增强复合材料涡轮轴结构失效模式分析方法的有效性。利用所建立模型预测了某型发动机低压涡轮轴的失效载荷及失效模式。     

基于自适应代理模型的结构动力可靠度分析方法

结构动力可靠度分析对于衡量结构的安全状态和工作性能具有重要的指导意义。采用一种同时考虑 动态激励载荷和材料力学性能参数随机性的动力可靠度计算高效方法,通过建立不确定性材料力学性能参数 与条件动力可靠度之间的 Kriging代理模型,推导动力可靠度的解析表达式;提出一个新的学习函数来构建自 适应的 Kriging代理过程,通过复合材料飞行器蒙皮骨架结构在随机振动载荷和随机材料力学性能参数共同作 用下的动力可靠度分析对所提方法的准确性与高效性进行验证。结果表明:所提方法不仅能够避免使用代理 模型对动力可靠度求解时由于使用数值积分所引入的误差,同时能够使用尽可能少的计算成本获得准确的动 力可靠度结果。