面向AI时代的纤维增强树脂基复合材料工艺仿真

纤维增强树脂基复合材料制造工艺是保证其产品结构效率和应用可靠性的关键,通过计算机进行工艺仿真是提高复合材料制造质量与降低制造成本的重要手段。传统工艺仿真依赖于制造过程中的物理化学机理,通过有限元/有限体积等数值计算方法,以及计算机图形学等辅助设计方法来求解相关机理模型的数学方程,目前已在增强体/预浸料的铺覆、树脂的渗透流动、热固性树脂的固化行为、热传导与热交换、非线性力学及残余应力与固化变形预测等方面得到广泛应用。近年来,人工智能(AI)的迅猛发展,其技术基础机器学习(ML)与人工神经网络(ANN)相结合,已用于增强体铺覆、液体成型工艺和热压罐工艺领域,主要目的是数据挖掘和建立降阶模型。前者可以建立工艺条件与制件固化质量、力学性能等之间的关系,后者则可以提高工艺仿真的计算效率。然而受限于纤维增强树脂基复合材料制造过程复杂、不可测、成本高的特点,在AI时代的起点,仅依赖实验获得的数据量难以满足ML的要求,同时数据驱动AI还面临模型代表性、普适性、可解释性不确定的问题。因此,基于物理化学机理的传统工艺仿真可为数据驱动ML仿真提供大量可靠数据,进而通过AI建立更多描述复合材料工艺的定量模型,扩展工艺仿真可计算的过程;同时,通过AI技术提高计算效率后,满足实时性要求的工艺仿真可进化为制造过程的数字孪生(DT),从而可为复合材料降低成本、提高全寿命周期管理的科学性提供新的技术支撑。

Effects of Lay-up Types of Out-of-autoclave Prepregs on Preparation Quality of L-shape Composite Laminates

Effects of layer quantities and stacking sequences on L-shape composite manufacturing qualities in using OOA(out-of-autoclave)prepregs were studied.The mechanisms of air evacuated in 5 kinds of lay-ups were revealed by image analysis of cut surfaces and thickness measurements.Results show that air in OOA prepregs is evacuated in two ways.Most of the air is forced out of layers directly by vacuum before air accesses in prepregs closed.Very little entrapped air moves perpendicularly to outer layers under hydrostatic resin pressure.When a laminate contains less than 16 layers,voids can hardly be found in layers.When a laminate contains more than 16 layers,voids cannot be expelled completely during the window of vertical movement.As for stacking sequences,the synergetic effect of slip function and nest function determines the thickness and voids content of laminates.Results show that the average of single layer thickness of unidirectional layers is the lowest,and the average of single layer thickness of quasi-isotropic layers is the highest.The voids content of quasi isotropic is the highest,which is consistent with the theoretical analysis.

核壳粒子增韧改性液态成型双马树脂性能及其机理

传统的液态成型双马来酰亚胺树脂(BMI)较低的韧性阻碍了其在航空航天领域的应用。通过在液态成型双马树脂网络中引入核壳粒子,利用核壳粒子具备独特的双层结构增韧改性双马树脂。采用扫描电子显微镜(SEM)对不同含量核壳粒子改性液态成型双马树脂体系断面形貌进行研究,SEM结果表明,改性的液态成型双马树脂固化物断裂表面的裂纹扩展明显受阻,显示韧性断裂形貌。研究了不同含量核壳粒子对液态成型双马树脂体系性能的影响,优选出最佳的核壳粒子含量。研究表明,改性固化物表现出优异的机械性能:拉伸强度108.8 MPa,提高了13.1%;断裂伸长率3.12%,提高了16.8%;弯曲强度190 MPa,提高了12.4%;KIC达到2.83 MPa/m^(1/2),提高了20.9%;GIc达到1619 J/m^(2),提高了54.6%;并且保持改性前树脂热性能及热失重性能,玻璃化转变温度Tg为292.3℃,5%热失重温度为401.0℃。