【新文速递】2024年9月5日复合材料SCI期刊最新文章
今日更新:Composite Structures 5 篇,Composites Part A: Applied Science and Manufacturing 3 篇,Composites Part B: Engineering 2 篇,Composites Science and Technology 1 篇
Composite Structures
Mechanical evaluation of multi-continuous interpenetrating phase composites based on Schwarz Primitive cellular structure
Jian Li, Jin Xu, Jiaxing Li, Yuyu Tian, Tengjie Li, Xicheng Huang
doi:10.1016/j.compstruct.2024.118516
基于Schwarz原始细胞结构的多连续互穿相复合材料力学性能评价
Interpenetrating phase composites (IPCs) have been extensively promoted due to their robust mechanical properties. To further obtain the enhanced properties and elucidate the underlying mechanical mechanism, we designed and manufactured the tri-continuous IPCs by filling hyperelastic PDMS into a 3D-printed Schwarz Primitive (P) cellular skeleton based on the viscoplastic polymer. Subsequently, the compressive properties, cyclic properties, and relaxation properties of the IPCs were experimentally investigated. Results demonstrated that interpenetrating can improve the compressive properties, reduce the relaxation behavior, and weaken the cyclic softening effect. By incorporating a user material subroutine in simulations, we analyzed the deformation behaviors of P cellular material and IPCs. Through a combination of experimental observations and simulated outcomes, we refined our understanding of the deformation mechanism of IPCs. Our analysis revealed that filled PDMS played a positive role in enhancing the mechanical performance of TC-IPCs through three key mechanisms: Firstly, it shears part of the external load of TC-IPCs. Secondly, it astricts the bending deformation in the skeleton, thereby preventing the stress drop induced by buckling. Thirdly, the interaction between PDMS and P cellular skeleton puts them in compressive stress in tri-direction, enhancing the overall mechanical properties. These findings contribute to advancing the development and application of IPCs.
互穿相复合材料以其优异的力学性能得到了广泛的应用。为了进一步获得增强的性能并阐明潜在的力学机制,我们通过将超弹性PDMS填充到基于粘塑性聚合物的3d打印Schwarz Primitive (P)细胞骨架中来设计和制造三连续IPCs。随后,对IPCs的压缩性能、循环性能和弛豫性能进行了实验研究。结果表明,互穿可以改善材料的压缩性能,降低材料的松弛行为,减弱循环软化效应。通过在模拟中加入用户材料子程序,我们分析了P细胞材料和IPCs的变形行为。通过实验观察和模拟结果的结合,我们完善了对ipc变形机制的理解。分析表明,填充PDMS对tc - ipc力学性能的提升主要有三个机制:一是剪切tc - ipc的部分外载荷;其次,它限制了骨架的弯曲变形,从而防止了屈曲引起的应力下降。第三,PDMS与P细胞骨架的相互作用使其在三方向上处于压应力状态,提高了整体力学性能。这些发现有助于推进IPCs的开发和应用。
Sensors integration for structural health monitoring in composite pressure vessels: A review
Bilal Meemary, Dmytro Vasiukov, Mylène Deléglise-Lagardère, Salim Chaki
doi:10.1016/j.compstruct.2024.118546
复合材料压力容器结构健康监测传感器集成研究进展
Filament-wound Composite Pressure Vessels (CPVs) are employed largely for gas or fluid storage under pressure in aerospace, automotive and naval industries. Composite vessels are subjected to harsh conditions such as critical loadings, extreme temperatures, and bursting; therefore, a permanent in-situ and online monitoring approach for the structural integrity of the vessels is essential. Hence, this review paper focuses on the description of the most trending used sensors such as piezoelectric (PZT and PVDF), piezoresistive (BP and MXene) and fiber optic (SOFO®, OBR and FBG) sensors, for developing a Structural Health Monitoring (SHM) approach to create self-sensing composite pressure vessels. The novelty of this review paper lies in providing an overview of existing works covering the integration of sensors in composite vessels, including sensor types, localization, and their impact on composite integrity. Particularly, an analysis of the literature is provided concerning the sensor’s integration and especially their monitored parameters, layout design and arrangement in CPVs. Additionally, the interaction between the host composite material and sensors is analyzed to understand how to integrate sensors with the minimum possible defects that alter the mechanical performance of composite vessels. Lastly, a discussion of a CPV’s SHM system is provided to offer researchers a foundation for upcoming experimental work
细丝缠绕复合压力容器(cpv)主要用于航空航天、汽车和船舶工业的压力下气体或流体储存。复合材料容器承受恶劣条件,如临界载荷、极端温度和爆裂;因此,对船舶结构完整性进行永久的原位在线监测至关重要。因此,本文重点介绍了最常用的传感器,如压电(PZT和PVDF),压阻(BP和MXene)和光纤(SOFO®,OBR和FBG)传感器,用于开发结构健康监测(SHM)方法,以创建自传感复合压力容器。这篇综述的新颖之处在于概述了复合材料容器中传感器集成的现有工作,包括传感器类型、定位及其对复合材料完整性的影响。特别地,对传感器的集成,特别是其监测参数、布局设计和布置等方面的文献进行了分析。此外,还分析了主复合材料与传感器之间的相互作用,以了解如何将传感器与可能改变复合容器机械性能的最小缺陷集成在一起。最后,对CPV的SHM系统进行了讨论,为后续的实验工作提供了基础
Evaluation of self-repair efficiency of polymers containing microcapsules using optical coherence tomography
Ewa Korzeniewska, Joanna Sekulska-Nalewajko, Jarosław Gocławski, Emilia Irzmańska, Agnieszka Adamus-Włodarczyk, Paweł Kozikowski
doi:10.1016/j.compstruct.2024.118525
利用光学相干断层成像技术评价含微胶囊聚合物的自修复效率
Self-healing polymers are used to improve the durability and strength of materials and provide them with a longer service life. The authors propose a new optical method for evaluating the self-repair efficiency in polymers containing microcapsules. The non-destructive method measures spatial profiles of a hole series obtained after a material puncture. Spatial images of holes acquired by optical coherence tomography were processed to get a surface profile. The reduction of the average volume or depth of the holes compared to the reference material allows self-healing efficiency calculation. For the presented method, tests were carried out to measure the self-repair efficiency of test materials with 5% and 10% mass of repair capsules compared to Ethe reference polymer without capsules. The volumetric efficiencies of self-repair obtained from 30 holes of each material, acquired 8 h after the puncture, were computed as 51.6% and 58.3% for the two repaired material types, respectively.
自修复聚合物用于提高材料的耐久性和强度,并提供更长的使用寿命。作者提出了一种新的光学方法来评价含微胶囊聚合物的自修复效率。该非破坏性方法测量材料穿孔后获得的孔系列的空间轮廓。对光学相干层析成像获得的孔洞空间图像进行处理,得到孔洞表面轮廓。与参考材料相比,孔的平均体积或深度的减少允许计算自愈效率。针对所提出的方法,对含有5%和10%质量的修复胶囊的测试材料的自修复效率进行了测试,并与不含胶囊的参比聚合物进行了比较。每一种材料的30个孔在穿刺后8 h的自我修复体积效率分别为51.6%和58.3%。
Investigation on 2D SiCf/SiC composite scribing mechanism by single- and double-grit
Yao Liu, Youzhe Wang, Zhigang Zhao, Linzheng Ye, Jinjie Zhou
doi:10.1016/j.compstruct.2024.118547
二维SiCf/SiC复合材料单粒和双粒刻划机理研究
To validate the proposed removal mechanism of 2D SiCf/SiC composite, single- and double-grit scribing experiments were conducted on the fiber woven surface (WS) and stacking surface (SS) along the 0°, 45°, and 90°. The results indicate that transverse fibers mainly undergo shear, tensile, and bending fractures. The removal modes of normal fibers are shear and bending fractures. The longitudinal fibers are damaged by tensile (cut-in side) and bending (cut-off side) fractures, accompanied by fiber peel-off. The removal forms of the matrix include crack propagation, ductile scratch, powdery removal, and brittle peel-off. The order of scribing force is FSS0 > FWS45 > FSS90 > FWS0. The maximum and minimum scribing force occur on SS0 and WS0, respectively, due to the powdery removal of matrix and fibers + matrix peel-off. The 2nd grit scribes the matrix layer and fiber tip in a very low depth to cause powdery and ductile removal, which exhibit the different material removal mechanism with the 1st grit. The scribing damage formed by 1st grit greatly reduces the force required by the 2nd grit for the same material removal volume. The coupling effect among grits in multi-grit scribing and grinding cannot be ignored.
为了验证所提出的二维碳化硅/碳化硅复合材料的移除机制,在纤维编织面(WS)和堆叠面(SS)上沿 0°、45° 和 90°进行了单粒和双粒划线实验。结果表明,横向纤维主要发生剪切、拉伸和弯曲断裂。正常纤维的破坏模式为剪切和弯曲断裂。纵向纤维的破坏方式为拉伸断裂(切入侧)和弯曲断裂(切断侧),并伴有纤维剥离。基体的剥离形式包括裂纹扩展、韧性划痕、粉末状剥离和脆性剥离。刻划力的顺序为 FSS0 > FWS45 > FSS90 > FWS0。由于基体和纤维的粉末状去除+基体剥离,SS0 和 WS0 上的划痕力分别最大和最小。第 2 号砂粒对基体层和纤维端部的刻划深度很低,造成粉末状和韧性去除,表现出与第 1 号砂粒不同的材料去除机理。在相同的材料去除量下,第 1 号磨粒形成的划痕损伤大大降低了第 2 号磨粒所需的作用力。在多磨粒划线磨削中,磨粒之间的耦合效应不容忽视。
Combined computational-experimental investigation of residual stresses and pre-cracking in mode I behaviour of thick adhesively bonded GFRP composite joints
Akash Sharma, Ali Shivaie Kojouri, Jialiang Fan, Anastasios P. Vassilopoulos, Veronique Michaud, Kalliopi-Artemi Kalteremidou, Danny Van Hemelrijck, Wim Van Paepegem
doi:10.1016/j.compstruct.2024.118549
厚粘接GFRP复合材料节点I型残余应力和预裂行为的计算-实验结合研究
This paper presents a novel Finite Element (FE) simulation approach to examine the mode I fracture of thick adhesive joints used particularly in the trailing edge of the wind turbine blades. The approach involved FE models of the DCB specimens focusing on aspects overlooked in the existing literature. There has been limited investigation on residual stresses caused by thermal mismatch between composites and adhesives. Similarly, the impact of generating notches/pre-cracks in the adhesive layer during the preparation of Double Cantilever Beam (DCB) specimens on residual stresses has received minimal attention. Additionally, the Cohesive Zone Model, commonly used for simulating elastoplastic adhesives, may be inadequate due to its inability to account for the plastic deformation of the adhesive. In the present work, the pre-cracks were virtually generated in DCB FE models so that their effect on the stresses within the joint could be examined, making it a novel contribution to the field. The components were assigned with appropriate thermal expansion coefficients, and a simulation of the cool-down process was conducted to determine the thermal residual stresses. Furthermore, the Drucker-Prager plasticity criteria were used to capture the elastoplastic behaviour of adhesives in the FE simulations. Concurrently, the T-stresses were assessed through numerical investigations. For validation, experiments were conducted on DCB specimens made of two cross-ply composite laminates bonded with a ∼ 10 mm thick layer of an epoxy-based adhesive. A good agreement between computational and experimental results was observed, confirming the effectiveness and reliability of the proposed approach.
本文提出了一种新的有限元模拟方法,用于研究风力发电机叶片后缘厚粘接接头的I型断裂。该方法涉及DCB试件的有限元模型,重点关注现有文献中忽略的方面。对于复合材料与胶粘剂之间的热失配引起的残余应力的研究有限。同样,在双悬臂梁(DCB)试件制备过程中,粘接层产生缺口/预裂纹对残余应力的影响也很少受到关注。此外,通常用于模拟弹塑性胶粘剂的内聚区模型可能不充分,因为它无法考虑胶粘剂的塑性变形。在本工作中,预裂缝在DCB有限元模型中虚拟生成,以便可以检查其对接头内应力的影响,使其成为该领域的新贡献。为零件分配适当的热膨胀系数,并对冷却过程进行模拟以确定热残余应力。此外,在有限元模拟中,采用Drucker-Prager塑性准则来捕捉胶粘剂的弹塑性行为。同时,通过数值研究对t应力进行了评估。为了验证,实验进行了DCB样品,该样品由两个交叉层合复合材料层合板与 ~ 10 mm厚的环氧基粘合剂层合而成。计算结果与实验结果吻合较好,验证了该方法的有效性和可靠性。
Composites Part A: Applied Science and Manufacturing
Synergistic enhancement of modulus and ductility in Mg matrix composites: A new strategy for GNPs&MgOnp and SiCp hybrid reinforcement
Xuanchang Zhang, Xuejian Li, Fanghan Chi, Hailong Shi, Muyuan Li, Youpeng Sun, Yunqiao Hao, Yuanyuan Zhang, Xiaoshi Hu, Chao Xu, Guohua Fan, Xiaojun Wang
doi:10.1016/j.compositesa.2024.108448
镁基复合材料模量和延性的协同增强:GNPs&MgOnp和SiCp混杂增强的新策略
SiC particles (SiCp) reinforced magnesium matrix composites (MMCs) exhibit elevated specific stiffness. However, the non-uniform distribution of SiCp and the interfacial cracking between the SiCp and Mg matrix compromise the ductility. This paper presents a novel approach to enhance the modulus and ductility of the MMCs by utilizing in-situ synthesized graphene nanoplatelets (GNPs) and MgO nanoparticles (MgOnp). The in-situ reaction of GNPs and MgOnp (GNPs&MgOnp) conducted at a high temperature (720 °C) demonstrates an improvement in the local agglomeration of SiCp compared to the conventional semi-solid temperature (590 °C). Moreover, the GNPs&MgOnp optimized interfacial structure and transferred the load during plastic deformation, inhibiting stress concentration and crack propagation at the interface of SiCp. The ductility and modulus are enhanced by approximately 70 % and 10 % compared to SiCp/Mg-6Zn composites, demonstrating the effectiveness of the strategy employing micro-nano hybrid reinforcement and synergistic enhancement of ductility and modulus.
SiC颗粒(SiCp)增强镁基复合材料(MMCs)具有较高的比刚度。然而,SiCp的不均匀分布和SiCp与Mg基体之间的界面开裂影响了材料的塑性。本文提出了一种利用原位合成石墨烯纳米片(GNPs)和MgO纳米颗粒(MgOnp)来提高MMCs模量和延展性的新方法。在高温(720 °C)下进行的GNPs和MgOnp的原位反应(GNPs&MgOnp)表明,与传统的半固体温度(590 °C)相比,SiCp的局部团聚得到了改善。此外,GNPs&MgOnp优化了界面结构,并在塑性变形过程中传递了载荷,抑制了SiCp界面的应力集中和裂纹扩展。与SiCp/Mg-6Zn复合材料相比,其延性和模量分别提高了约70 %和10 %,表明采用微纳混合增强策略和协同增强延性和模量的有效性。
Experimental characterisation framework for laminate free edges by Digital Image Correlations and validation of numerical predictions
Boming Zhang, David Kellermann, Garth Pearce
doi:10.1016/j.compositesa.2024.108449
层压板自由边缘的数字图像相关实验表征框架及数值预测的验证
This paper develops an accurate experimental framework to measure interlaminar strains on laminate free edges. Digital Image Correlation (DIC) is used with an ultra-fine speckle pattern and macro lens to resolve strain fields with a resolution of ∼ 15 µm, allowing for through-thickness deformation and strain mapping. Data analysis techniques are developed to denoise the strain field and discount the effect of random local fibre distribution. The major application of the framework is to validate numerical predictions, and it is demonstrated on angle-ply laminates over a range of ply orientations. A micropolar-based finite-element approach was compared to both a classical finite-element approach and the DIC-acquired interlaminar strain fields. Key improvements by the results include significantly overcoming the stark inconsistency of classical normal strains, and reducing the discrepancies of shear strains from 30 % to 3 ∼ 10 %. The outcomes can be extended to destructive failure analysis and the free-edge study of various other composite architectures.
本文提出了一种测量层合板自由边缘层间应变的精确实验框架。数字图像相关(DIC)与超细散斑图案和微距透镜一起使用,以 ~ 15 µm的分辨率解析应变场,允许进行全厚度变形和应变映射。数据分析技术的发展是为了去噪应变场和消除随机局部纤维分布的影响。该框架的主要应用是验证数值预测,并在各种厚度方向的角层合板上进行了演示。将基于微极的有限元方法与经典有限元方法和dic获得的层间应变场进行了比较。结果的主要改进包括显著克服经典正常应变的明显不一致性,并将剪切应变的差异从30 %减少到3 ~ 10 %。所得结果可推广到各种复合材料结构的破坏分析和自由边缘研究。
Controllable and lightweight ZIF-67@PAN derived Co@C nanocomposites with tunable and broadband microwave absorption
Mudasir Ahmad, Muhammad Rizwan Tariq, Menier-Al-Anazi, Idrees Khan, Baoliang Zhang
doi:10.1016/j.compositesa.2024.108445
可控和轻量级ZIF-67@PAN衍生Co@C纳米复合材料可调谐和宽带微波吸收
Metal-organic framework-based carbon–carbon composite represent a novel class of microwave-absorbing materials (MAMs). However, obtaining lightweight and highly efficient absorbers with a lower filling ratio and larger effective absorption bandwidth (EAB) poses a challenge. In this study, we developed a controllable preparation method for ZIF-67 template polyacrylonitrile-wrapped nanocomposite (ZIF-67@PAN) precursor. This was achieved through radical polymerization of acrylonitrile (AN) initiated by azobisisobutyronitrile (AIBN). Subsequent annealing at high temperatures produced a lightweight nitrogen and oxygen-doped graphite layer-wrapped Co@C smart material (Co@C1, Co@C2, and Co@C3) with tunable microwave absorption properties (MAP). The results demonstrate that Co@C2 achieved a minimum reflection loss (RLmin) value of −50.20 dB at a thickness of 2.0 mm with an EAB of 6.1 only at a filler content of only 13 %. Therefore, this work offers a controllable preparation method and introduces a simple and facile approach for creating efficient, lightweight micro and nano-sized microwave-absorbing materials.
金属-有机骨架碳-碳复合材料是一类新型的微波吸收材料。然而,如何获得更低填充率、更大有效吸收带宽(EAB)的轻质高效吸光剂是一个挑战。在本研究中,我们开发了一种可控的ZIF-67模板聚丙烯腈包覆纳米复合材料(ZIF-67@PAN)前驱体的制备方法。这是通过偶氮二异丁腈(AIBN)引发的丙烯腈(AN)自由基聚合实现的。随后在高温下退火制备了轻质的氮和氧掺杂石墨层包裹Co@C智能材料(Co@C1, Co@C2和Co@C3),具有可调谐的微波吸收特性(MAP)。结果表明,Co@C2在厚度为2.0 mm时的最小反射损失(RLmin)值为−50.20 dB,当填料含量为13% %时,EAB值为6.1。因此,这项工作提供了一种可控的制备方法,并引入了一种简单易行的方法来制造高效、轻量化的微纳米级微波吸收材料。
Composites Part B: Engineering
Machine learning based damage identification in SiC/SiC composites from acoustic emissions using autoencoders
C. Muir, T. Gibson, A. Hilmas, A.S. Almansour, K. Sevener, J.D. Kiser, T.M. Pollock, S. Daly, C. Smith
doi:10.1016/j.compositesb.2024.111802
基于机器学习的基于声发射的SiC/SiC复合材料损伤识别
Developing the ability to leverage machine learning (ML) to identify damage mechanisms in heterogeneous materials from their acoustic emissions (AE) has wide-reaching ramifications for multi-modal experimentation. It would allow researchers to augment damage triangulation, lifetime prediction, and high-resolution optical studies with complementary mechanism-informed data streams. However, developing this capability hinges on the collection of ground truth acoustic libraries from damage in realistic geometries. Due to time and monetary considerations, there is a dearth of ground truth libraries which can be used to robustly characterize ML mechanism identification frameworks. Addressing this gap, we present a multi-modal acoustic emission and x-ray computed tomography study where AE is gathered, and subsequently labeled, from SiC/SiC unidirectional composites under monotonic tension. This library is used to demonstrate that acoustic signals from early fiber breaks are obscured by matrix cracking. A first-order micromechanical model is used to explain the origin of this obscuring effect, and identify fundamental limitations of unsupervised frameworks. An autoencoder-based anomaly detector approach is used for the first time to overcome these limitations, additionally demonstrating that the frequency distribution of fiber break acoustic signals is narrow. Implications of these findings for enhanced multi-modal testing and online health monitoring are discussed, and strategies for implementation of supervised damage mechanism identification frameworks are proposed.
开发利用机器学习(ML)从异质材料的声发射(AE)中识别损伤机制的能力,对多模态实验具有广泛的影响。它将允许研究人员通过补充机制信息数据流来增强损伤三角测量、寿命预测和高分辨率光学研究。然而,开发这种能力取决于收集真实几何损坏的地面真实声学库。由于时间和金钱方面的考虑,缺乏可用于稳健地表征ML机制识别框架的基础真理库。为了解决这一空白,我们提出了一项多模态声发射和x射线计算机断层扫描研究,其中在单调张力下从SiC/SiC单向复合材料中收集声发射并随后标记声发射。该库用于证明早期纤维断裂的声信号被基体开裂所掩盖。一阶微观力学模型被用来解释这种模糊效应的起源,并确定无监督框架的基本局限性。一种基于自编码器的异常检测方法首次被用于克服这些限制,此外还证明了光纤断裂声信号的频率分布很窄。这些发现对增强多模态测试和在线健康监测的意义进行了讨论,并提出了实施监督损伤机制识别框架的策略。
Limit states of thin-walled composite structures with closed sections under axial compression
Patryk Różyło
doi:10.1016/j.compositesb.2024.111813
轴压下封闭截面薄壁复合结构的极限状态
The subjects of the study were thin-walled composite columns with closed cross sections manufactured using the autoclave technique. The composite profiles were characterized by the fact that they had a constant height and arrangement of laminate layers, however, varied cross-sectional shapes. The study was conducted using several interdisciplinary experimental research methods and advanced numerical simulations. In the course of the research, both forms of structural stability loss were registered, and damage to composite structures was assessed. In the course of the research, the influence of the shape of the cross-section on the stability and load-carrying capacity of the structure was evaluated. A measurable effect of the conducted research was the determination of the structure's post-buckling equilibrium paths, which made it possible to determine the structure's behavior in the full range of loading. In addition, the author’s numerical models developed enabled validation of parallel experimental studies. The developed numerical models were based on a failure criterion known as progressive failure analysis - which allowed a thorough assessment of the failure mechanism of the composite material.
该研究的对象是薄壁复合柱与封闭的横截面制造使用高压灭菌技术。复合型材的特点是它们具有恒定的高度和层压层的排列,然而,不同的横截面形状。本研究采用了多种跨学科的实验研究方法和先进的数值模拟方法。在研究过程中,记录了两种形式的结构稳定性损失,并对复合结构的损伤进行了评估。在研究过程中,评估了截面形状对结构稳定性和承载能力的影响。所进行的研究的一个可测量的效果是确定了结构的后屈曲平衡路径,这使得确定结构在全载荷范围内的行为成为可能。此外,作者开发的数值模型能够验证平行实验研究。开发的数值模型是基于一种被称为渐进失效分析的失效准则,该准则允许对复合材料的失效机制进行彻底的评估。
Composites Science and Technology
Micro-buckling Resistant Unidirectional Glass Fiber Composites with Excellent Transverse and Longitudinal Flexural Properties from Cross-Linking by Nano-/Micro-Aramid Fibers
Fankai Lin, Mingxin Ye, Xin Min, Zhaohui Huang, Fei Cheng, Xiaozhi Hu
doi:10.1016/j.compscitech.2024.110841
纳米/微芳纶交联制备的具有优异横向和纵向弯曲性能的抗微屈曲单向玻璃纤维复合材料
This study aims at obtaining an effective structural design strategy for stronger and more reliable Unidirectional glass fiber (UD-GF) composites by in-situ formed cross-linking from randomly distributed nano-/micro- Aramid pulp (AP) fibers. The flexural strength and stiffness have shown substantial improvements in both the transverse and longitudinal directions due to the AP cross-linking and the "brick-slurry" structure. With AP of 8 g/m2, up to 60-70% improvement in flexural strengths (both transverse and longitudinal directions) and up to 20-37% improvement in “effective modulus” have been observed. The noticeable longitudinal improvements have been attributed to the resin reinforcement and interlayer cross-linking provided by ultra-thin AP interlayers, and the resultant improvement in micro-buckling resistance under compression. Since sparsely distributed nano-/micro-AP can be readily incorporated in pultrusion and pre-preg manufacturing processes, this study is not only important for micro-mechanism study, but also provides a plausible improvement in manufacturing.
本研究旨在通过随机分布的纳米/微芳纶纸浆(AP)纤维原位形成交联,获得一种更强、更可靠的单向玻璃纤维(UD-GF)复合材料的有效结构设计策略。由于AP交联和“砖浆”结构,在横向和纵向上,抗弯强度和刚度都有了实质性的改善。当AP为8 g/m2时,抗弯强度(横向和纵向)可提高60-70%,“有效模量”可提高20-37%。显著的纵向改善归功于超薄AP夹层提供的树脂增强和层间交联,以及由此带来的抗压缩微屈曲性能的提高。由于稀疏分布的纳米/微ap可以很容易地加入到拉挤和预浸制程中,因此该研究不仅对微观机理研究具有重要意义,而且为制造提供了合理的改进。
