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【新文速递】2024年4月19日复合材料SCI期刊最新文章

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今日更新:Composite Structures 6 篇,Composites Part A: Applied Science and Manufacturing 1 篇,Composites Part B: Engineering 2 篇,Composites Science and Technology 1 篇

Composite Structures

Rapid prediction of the cure-induced distortion of newly developed composite parts via transfer learning

Jiawei Guo, Shuting Liu, Yingguang Li, Qinlu Meng, Xu Liu, Xiaozhong Hao

doi:10.1016/j.compstruct.2024.118139

基于迁移学习的复合材料零件固化变形快速预测

Accurately predicting Cure-Induced Distortion (CID) is paramount to ensuring manufacturing precision. Existing prediction models heavily rely on material parameters associated with the CID, which presents challenges for newly developed composites due to the time-consuming, expensive, and limited accuracy of parameter characterization processes. With recognizing the shared curing mechanism across various composites, this paper introduces a transfer learning-based approach that leverages a small dataset of practical CID data from the newly developed composite and historical knowledge from existing composites to achieve rapid and accurate CID predictions. This approach was validated for two typical CID prediction cases by implementing a transfer learning framework, and various sampling methods were explored to assess the stability and repeatability of prediction results. The results indicate that the proposed method can predict the CID within a 5% margin of error. This paper offers a promising approach for predicting CID in the design and manufacturing processes.

准确预测固化诱发变形(CID)对保证制造精度至关重要。现有的预测模型严重依赖于与CID相关的材料参数,由于参数表征过程耗时、昂贵且精度有限,这给新开发的复合材料带来了挑战。在认识到各种复合材料之间的共享固化机制后,本文引入了一种基于迁移学习的方法,该方法利用来自新开发复合材料的实际CID数据的小数据集和来自现有复合材料的历史知识来实现快速准确的CID预测。通过迁移学习框架对两个典型的CID预测案例进行了验证,并探索了各种采样方法来评估预测结果的稳定性和可重复性。结果表明,该方法可以在5%的误差范围内预测CID。本文为设计和制造过程中CID的预测提供了一种有前途的方法。


Characterization of a two-step laser paint stripping process on CFRP

Man Xu, Sen Yang, Xinyi Liu, Lin Li, Yu Wan, Chenzhuo Wang, Meng Wu, Youdong Gao, Mian Zhong, Biyi Wang, Yong Jiang

doi:10.1016/j.compstruct.2024.118140

CFRP两步激光脱漆工艺的表征

This work presents a two-step non-destructive method for cleaning the surface paint of CFRP. The method combines ablation and vibration, using a pulsed laser with a wavelength of 1064 nm. The effects of laser power, beam and path overlap rate on the removal of paints are investigated. The analysis focuses on the cleaning and the damage threshold of the paints and fibers. Additionally, the study analyzed the thermal accumulation effect and fiber damage resulting from various laser parameters. The cleaned samples were analyzed for micro-morphology, elemental composition, surface roughness, three-dimensional morphology, and contact angle to demonstrate the modulation of derivatization phenomena of CFRP surface paints under different cleaning states using this method. This points to the reliability and feasibility of the relevant treatment parameters and provides a reference for the subsequent research on the practical application of laser cleaning.

本文提出了一种两步法无损清洗CFRP表面涂料的方法。该方法结合了烧蚀和振动,使用波长为1064 nm的脉冲激光器。研究了激光功率、光束和路径重叠率对涂料去除的影响。重点分析了涂料和纤维的清洗和损伤阈值。此外,研究还分析了不同激光参数对光纤的热积累效应和损伤。对清洗后的样品进行微观形貌、元素组成、表面粗糙度、三维形貌和接触角分析,验证了该方法对CFRP表面涂料在不同清洗状态下衍生化现象的调节作用。这指出了相关处理参数的可靠性和可行性,为后续激光清洗实际应用的研究提供了参考。


Double shooting method for FRCM reinforced systems in debonding problems

Yu Yuan, Gabriele Milani

doi:10.1016/j.compstruct.2024.118136

钢筋混凝土加固体系脱粘问题的双射法研究

The debonding process in FRCM (Fiber Reinforced Cementitious Matrix) strengthened brittle substrates, such as concrete and masonry, is characterized by complex failure modes that include debonding at both the external and internal interfaces of the composite, as well as damage to the mortar matrix. This study addresses this problem classically as a mode-II fracture process by accounting for the one-dimensional non-linear interfacial shear stress-slip relationship combined with matrix axial non-linearity. The approach employed considers the longitudinal displacements of both the inner and outer layers of mortar, along with that of the fiber textile, as unknowns, and analytically solves the second-order ordinary differential equation (ODE) system that governs the debonding problem. Then, the boundary value problem (BVP) is transformed into an initial value problem (IVP) and a double shooting method is proposed to find displacements and stresses along the bonded length in the presence of non-linearity. The appropriate initial values of matrix layer displacements, satisfying the required boundary conditions, are efficiently determined through a two-dimensional bisection method working on rectangular and triangular patches. The softening behavior of both mortar layers and interfaces between mortar and fiber are taken into account using jagged constitutive relationships to enhance convergence. The numerical calculation speed, robustness, and key simulation parameters are thoroughly discussed. Moreover, the proposed numerical approach is compared with existing experimental data and models, on both concrete and masonry FRCM-reinforced specimens. The influence of mortar failure and interfacial strength is also explored. The model demonstrates its ability to effectively reproduce the global bond behavior observed in experimental studies, while capturing the local behavior and simulating various failure modes observed in the tests.

FRCM(纤维增强胶凝基质)增强脆性基体(如混凝土和砌体)的脱粘过程具有复杂的破坏模式,包括复合材料外部和内部界面的脱粘以及砂浆基体的破坏。考虑到一维非线性界面剪应力-滑移关系和基体轴向非线性,本研究将该问题经典地描述为ii型断裂过程。所采用的方法考虑了砂浆内层和外层的纵向位移,以及纤维织物的纵向位移,作为未知数,并解析地解决了控制脱粘问题的二阶常微分方程(ODE)系统。然后,将边值问题(BVP)转化为初值问题(IVP),提出了在非线性条件下沿键长方向求位移和应力的双射击方法。通过对矩形块和三角形块进行二维平分的方法,有效地确定了满足边界条件的矩阵层位移初始值。采用锯齿状本构关系,考虑砂浆层和砂浆与纤维界面的软化行为,增强收敛性。详细讨论了数值计算速度、鲁棒性和关键仿真参数。此外,将本文提出的数值方法与现有的混凝土和砌体frcm加筋试件的实验数据和模型进行了比较。探讨了砂浆破坏和界面强度的影响。该模型能够有效地再现实验研究中观察到的整体键行为,同时捕获局部行为并模拟试验中观察到的各种破坏模式。


A multi-responsive actuator with sensing capability based on poly (N-isopropyl acrylamide)/poly (sodium acrylate) Janus hydrogels

Jinkun Lin, Jialei Li, Weiheng Gong, Yongjia Liu, Yuxuan Ai, Aihua He, Huarong Nie

doi:10.1016/j.compstruct.2024.118141

 

基于聚(n -异丙基丙烯酰胺)/聚(丙烯酸钠)Janus水凝胶的具有传感能力的多响应驱动器

A Janus hydrogel composed of temperature-responsive poly (N-isopropyl acrylamide) (PNIPAM) and pH-responsive poly (sodium acrylate) (PSA) was fabricated from inexpensive monomers using a facile synthesis route. The asymmetric swelling between PNIPAM and PSA in different media and at different temperatures makes the Janus hydrogels have a multi-stimuli response, meanwhile, the interpenetrating layer between PNIPAM and PSA indicated a good interfacial adhesion for easy transfer of internal stress and deformation. Thus, the Janus hydrogels exhibited excellent advantages in actuator/sensor engineering, demonstrating the potential to grip and release objects in toxic media, encrypt, monitor and control safety in chemical production, and alert temperature of flammable and explosive solvents. In addition, the features of the Janus hydrogels incorporated with carbon nanotubes, such as the high sensitivity, large stretchability, and rapid and linear response, enabled their application as strain sensors for wearable technologies in the recognition of body movement and health detection.

以廉价单体为原料,采用简便的合成方法制备了温度响应型聚n -异丙基丙烯酰胺(PNIPAM)和ph响应型聚丙烯酸钠(PSA)的Janus水凝胶。PNIPAM和PSA在不同介质和温度下的不对称膨胀使Janus水凝胶具有多刺 激响应,同时PNIPAM和PSA之间的互穿层具有良好的界面附着力,易于传递内应力和变形。因此,Janus水凝胶在执行器/传感器工程中表现出优异的优势,展示了在有毒介质中抓取和释放物体的潜力,加密,监测和控制化学生产中的安全,以及易燃易爆溶剂的温度警报。此外,Janus水凝胶与碳纳米管结合的特点,如高灵敏度、大拉伸性、快速线性响应等,使其能够作为可穿戴技术的应变传感器应用于身体运动识别和健康检测。


Influence of Oxygen/Argon/Nitrogen multi-component plasma modification on interlayer toughening of UHMWPE fiber reinforced composites

Yuwei Zhao, Chunyue Fang, Lixia Jia, Bao Shi, Zhenhong Chen, Xiayun Zhang, Sainan Wei, Yuefen Han, Zixuan Liu, Ruosi Yan

doi:10.1016/j.compstruct.2024.118142

氧/氩/氮多组分等离子体改性对超高分子量聚乙烯纤维增强复合材料层间增韧的影响

The study reveals the influence of glow discharged three gas sources of Oxygen/Argon/Nitrogen plasma modification on interlayer toughening of ultra-high molecular weight polyethylene (UHMWPE) fiber reinforced composite. The failure modes under bending, tensile and interlayer fracture toughness testing were analyzed through acoustic emission (AE) technology. The results showed that Oxygen/Argon/Nitrogen multi-component plasma modified fiber introduced more hydrophilic groups such as hydrogen and hydroxyl groups, and significantly enhanced the binding of fiber and matrix. The GⅠC (Mode-I interlaminar fracture toughness) of multi-component plasma modified composites exhibited increased by 61.67%, 40.88% and 18.01% compared to untreated, Oxygen and Oxygen/Argon plasma, respectively, while GⅡC (Mode-Ⅱ interlaminar fracture toughness) increased by 38.57%, 25.57% and 23.09%. AE cluster analysis exhibited that multi-component plasma modified composites formed an energy dissipation mechanism dominated by fiber breakage. Additionally, the oxygen, argon, and nitrogen plasma modification have a synergistic effect on interlayer toughening.

研究了放电氧/氩/氮三种气源等离子体改性对超高分子量聚乙烯(UHMWPE)纤维增强复合材料层间增韧的影响。利用声发射(AE)技术分析了材料在弯曲、拉伸和层间断裂韧性测试下的破坏模式。结果表明,氧/氩/氮多组分等离子体改性纤维引入了更多的氢、羟基等亲水性基团,显著增强了纤维与基体的结合。多组分等离子体改性复合材料的i型层间断裂韧性(GⅠC)比未处理、氧和氧/氩等离子体分别提高了61.67%、40.88%和18.01%,而GⅡC (Mode-Ⅱ)层间断裂韧性分别提高了38.57%、25.57%和23.09%。声发射聚类分析表明,多组分等离子体改性复合材料形成了以纤维断裂为主的能量耗散机制。此外,氧、氩、氮等离子体改性对层间增韧有协同作用。


Compression after impact (CAI) failure mechanisms and damage evolution in large composite laminates: High-fidelity simulation and experimental study

Peyman Shabani, Lucy Li, Jeremy Laliberte, Gang Qi

doi:10.1016/j.compstruct.2024.118143

大型复合材料层合板冲击后压缩(CAI)破坏机制与损伤演化:高保真模拟与实验研究

This study focuses on developing and validating a high-fidelity finite element model for predicting damage evolution and residual strength in fiber-reinforced composite panels. Impact and compression after impact (CAI) tests were conducted at both barely visible impact damage (BVID) and clearly visible impact damage (CVID) levels. The ASTM D7137 standard 100 mm × 150 mm CAI coupons were inadequate to cover the range of experimental studies required for model validation. Therefore, larger 254 mm × 304.8 mm laminates were investigated under two CAI testing conditions: one a scaled-up version of ASTM standard coupon, and the other with additional anti-buckling support plates to reduce unsupported areas to 127 mm × 177.8 mm. The model captured inter- and intra-laminar failure modes, including fiber breakage, splitting, kinking, pull-out, and crushing as well as matrix cracking, delamination, and their interactions. This was achieved by cohesive zone modeling technique and enhancing the LaRC05 failure criteria through modeling the fiber damage evolution and utilizing an efficient search algorithm to determine the matrix fracture plane and fiber kink band angle. This study underscores the efficacy of the high-fidelity modeling approach in accurately predicting both impact damage and CAI strength in typical aircraft impact damage scenarios. Additionally, it provides insights into complex CAI failure mechanisms and energy release associated with various damage modes and highlights the effect of global buckling on the failure behavior and compressive strength of composite laminates. Furthermore, it shows that the proposed fixture with support plates is suitable for testing a broader range of impact scenarios without experiencing global buckling.

本研究的重点是开发和验证高保真有限元模型,用于预测纤维增强复合材料板的损伤演变和剩余强度。在几乎不可见的冲击损伤(BVID)和清晰可见的冲击损伤(CVID)水平下进行冲击和冲击后压缩(CAI)试验。ASTM D7137标准100 mm × 150 mm CAI券不足以涵盖模型验证所需的实验研究范围。因此,在两种CAI测试条件下,研究了较大的254 mm × 304.8 mm层压板:一种是ASTM标准券的放大版本,另一种是额外的抗屈曲支撑板,以减少不受支撑的面积到127 mm × 177.8 mm。该模型捕获了层间和层内的破坏模式,包括纤维断裂、劈裂、扭结、拔出和破碎,以及基体开裂、分层及其相互作用。采用内聚区建模技术,通过模拟纤维损伤演化,利用高效搜索算法确定基体断裂面和纤维扭结带角,增强了LaRC05失效准则。该研究强调了高保真建模方法在准确预测典型飞机冲击损伤场景中的冲击损伤和CAI强度方面的有效性。此外,它还提供了与各种损伤模式相关的复杂CAI破坏机制和能量释放的见解,并强调了整体屈曲对复合材料层合板破坏行为和抗压强度的影响。此外,它表明,所提出的夹具与支撑板适用于测试更广泛的冲击场景,而不会经历整体屈曲。


Composites Part A: Applied Science and Manufacturing

Random modeling of hemp fibers mechanical properties

Chiara Pepi, Maria Eleonora Pipistrelli, Massimiliano Gioffrè

doi:10.1016/j.compositesa.2024.108203

麻纤维力学性能的随机建模

The growing interest in vegetal fiber-based composite materials for reinforcing structural elements is prompting researchers to consider the inherent randomness, arising from various factors which are complex to model. For this reason a general probabilistic approach seems more appropriate to model all uncertainties regardless where they come from. In this paper, factory produced hemp ropes, and their components, are tested to obtain their tensile mechanical properties. In particular, 120 fibers with four different lengths, 55 yarns, 33 strands and 64 ropes are used to obtain a first statistical characterization of tensile strength, strain and Young modulus. These results are used to calibrate two commonly used random models such as Gaussian and three-parameters Weibull distributions and to give both qualitative and quantitative complete random characterization of the tensile properties of each hemp rope components. The obtained results are crucial to estimate vegetal fiber-based composite materials structural response.

人们对植物纤维基复合材料增强结构构件的兴趣日益浓厚,这促使研究人员考虑其固有的随机性,这些随机性由各种复杂的因素引起,难以建模。由于这个原因,一般的概率方法似乎更适合于对所有不确定性进行建模,而不管它们来自哪里。本文对工厂生产的麻绳及其组成部分进行了拉伸力学性能测试。特别地,使用了四种不同长度的120根纤维,55根纱线,33股和64根绳索,以获得抗拉强度,应变和杨氏模量的首次统计特性。这些结果被用来校准两种常用的随机模型,如高斯分布和三参数威布尔分布,并给出了定性和定量的完全随机表征麻绳各组分的拉伸性能。所得结果对于估计植物纤维基复合材料的结构响应具有重要意义。


Composites Part B: Engineering

Self-standing and compressible SiCnw/SiCnf composite aerogel via free carbon in-situ transformation mechanism: towards thermal and electromagnetic wave protection

Tiansheng Wang, Menghang Feng, Zichen Xiang, Zhi Song, Hualiang Lv, Yi Hou, Lixi Wang, Qitu Zhang

doi:10.1016/j.compositesb.2024.111454

 

独立可压缩SiCnw/SiCnf复合气凝胶通过自由碳原位转化机理:对热和电磁波的保护

SiC nanofiber-based composite aerogel represents a promising lightweight, high-temperature-resistant, and broadband-absorbing material. However, the residual carbon phase during the pyrolysis process would threaten the high-temperature oxidation tolerance. Herein, a free carbon in-situ transformation (FCIT) strategy was proposed to convert the amorphous free carbon on the surface of SiC nanofibers into SiC nanowires, constructing a multi-scale SiC nanowire/SiC nanofiber (SiCnw/SiCnf) composite aerogel. The SiCnw great broaden the inner fibrous framework, and the hierarchical network offers great enhancement for EM attenuation, compression resistance and thermal insulation. The self-standing composite aerogel possesses excellent flexibility (1500 cycles in 180°-bending test) and compression resistance (100 cycles at 40% strain). With only 10 wt% filler content, the SiCnw/SiCnf sample displays an effective absorption bandwidth (EAB) of 8.81 GHz (9.19-18.00 GHz) at a thickness of 2.94 mm. Even after enduring oxidation at 800 °C, the EAB still remains substantial at 6.92 GHz (11.08-18.00 GHz). Moreover, the outstanding mechanical performance were also retained under high temperature and oxidation environment due the reduced density and thermal conductivity. Therefore, the multifunctional SiCnw/SiCnf composite aerogel prepared by FCIT strategy could be served as efficient thermal and EMW protection candidate.

碳化硅纳米纤维基复合气凝胶是一种很有前途的轻质、耐高温、宽带吸收材料。然而,热解过程中残留的碳相会对高温耐氧化性造成威胁。本文提出了自由碳原位转化(FCIT)策略,将SiC纳米纤维表面的非晶态自由碳转化为SiC纳米线,构建了多尺度SiC纳米线/SiC纳米纤维(SiCnw/SiCnf)复合气凝胶。SiCnw极大地扩大了内部纤维框架,分层网络对电磁衰减、抗压缩和隔热有很大的增强。自立式复合气凝胶具有优异的柔韧性(在180°弯曲试验中可循环1500次)和抗压性(在40%应变下可循环100次)。当填料含量仅为10 wt%时,SiCnw/SiCnf样品在厚度为2.94 mm时的有效吸收带宽(EAB)为8.81 GHz (9.19-18.00 GHz)。即使经过800°C的持久氧化,EAB在6.92 GHz (11.08-18.00 GHz)时仍然保持可观。此外,由于密度和导热系数降低,在高温氧化环境下仍能保持优异的力学性能。因此,采用FCIT策略制备的多功能SiCnw/SiCnf复合气凝胶可以作为高效的热防护和EMW防护的候选材料。


An integrative warning-protection shear thickened composite sponge towards sensing performance and impact resistance with excellent flame retardant

Yucheng Pan, Min Sang, Junshuo Zhang, Zimu Li, Shuai Liu, Zhentao Zhang, Qian Ma, Xinglong Gong

doi:10.1016/j.compositesb.2024.111466

 

一种具有传感性能、抗冲击性能和优异阻燃性能的综合预警保护剪切增厚复合海绵

The mechanical shock and thermal damage generally exist together in hazardous environment, whereas traditional single protective materials are difficult to achieve all-round protection under extreme environment. Herein, to realize the integration of multifunctional abilities about impact resistance, flame-retardant and sensing performance, a “solid-liquid host-guest” structural shear thickened composite sponge is proposed, which flame-retardant shear thickening fluids with an extraordinary thickening ratio of 2183.95 % continuously disperse in 3D sponge matrix. The resulting composite sponge effectively attenuates the impact force by nearly 80% with the thickness of only 4 mm via a cooperation between the effect of shear hardening and structure densification. Meanwhile, after burning on the alcohol flame for 12 s, the composite sponge with 7 wt.% fire-retardant additive maintains a complete morphology and realizes self-extinguishing with a reliable flame-retardant ability. Attributed to the good electrical conductivity of shear thickening fluid, the composite sponge serves favorably in human body monitoring, impact sensing and fire warning. In a word, this multifunctional lightweight composite sponge is expected to realize the integration of early warning and protection, which is a competitive candidate material for the intelligent protection in complex environments.

在危险环境下,机械冲击和热损伤一般同时存在,传统的单一防护材料难以在极端环境下实现全方位防护。为实现抗冲击、阻燃、传感等多功能性能的集成,提出了一种“固-液主客”结构剪切增稠复合海绵,其阻燃剪切增稠流体在三维海绵基体中连续分散,增稠比达到2183.95%。通过剪切硬化和组织致密化的共同作用,得到的复合海绵在厚度仅为4 mm的情况下,有效地衰减了近80%的冲击力。同时,添加7 wt.%阻燃剂的复合海绵在酒精火焰上燃烧12s后,形态保持完整,实现自熄,阻燃能力可靠。由于剪切增稠流体具有良好的导电性,复合海绵在人体监测、冲击传感、火灾报警等方面具有良好的应用前景。总之,该多功能轻量化复合海绵有望实现预警与防护一体化,是复杂环境下智能防护的极具竞争力的候选材料。


Composites Science and Technology

Translaminar-envelope ply for CFRP mechanical enhancement

Jiahe Ma, Qiang Xu, Haowei Zhang, Lei Miao, Weidong Zhu, Yinglin Ke

doi:10.1016/j.compscitech.2024.110594

 

跨层包络层用于CFRP机械增强

Pursuing the trend of ply-level innovation in the field of high-performance CFRP composites, a pseudo-woven layup configuration has been developed by interlacing a thin-ply prepreg in the translaminar-envelope manner space-orthogonally inside a homogenized 4-ply sub-laminate to acquire mechanical superiorities for the global multidirectional laminate. This evolved layup structure possesses the stiffening feedbacks on in-plane principal properties by the locally-regulated 0° ply amount, and exerts the multi-interface synergy on shear-driven interlaminar fractures by the long-acting binding action. Further, the high robustness of structural performances has been revealed by resistance and tolerance against severe low-velocity impact damage, achieving up to 60% decrease in the projected delamination area and over 60% increase in the post-impact compressive strength. The translaminar-envelope layup configuration is expected to enhance the service capability of CFRP laminates.

在高性能CFRP复合材料领域,追求层序创新的趋势,通过在均匀的4层亚层压板中以跨层包覆的方式空间正交地交错薄层预浸料,开发了一种伪编织层压板结构,以获得全局多向层压板的力学优势。这种演化的铺层结构通过局部调节的0°铺层量对面内主要性能产生强化反馈,并通过长效结合作用对剪切驱动的层间裂缝发挥多界面协同作用。此外,对严重低速冲击损伤的抵抗力和容忍度显示了结构性能的高鲁棒性,预计分层面积减少60%,冲击后抗压强度增加60%以上。跨层包络层合结构有望提高碳纤维复合材料层合板的使用性能。



来源:复合材料力学仿真Composites FEM
ACTMechanicalAdditiveSystemMAGNET振动断裂复合材料非线性燃烧化学化机材料
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【新文速递】2024年4月8日复合材料SCI期刊最新文章

今日更新:Composites Part A: Applied Science and Manufacturing 2 篇,Composites Part B: Engineering 1 篇,Composites Science and Technology 2 篇Composites Part A: Applied Science and ManufacturingUnveiling the cutting force of multiphase fibers and particle reinforced polymer matrix composites based on multiphase microstructure: An experimental and theoretical studyWeiwei Xu, Songmei Yuan, Qilin Li, Xiaoxing Gao, Wenzhao An, Liyu Wangdoi:10.1016/j.compositesa.2024.108199 基于多相微结构揭示多相纤维和颗粒增强聚合物基复合材料的切削力:实验与理论研究To prevent excessive damage caused by high cutting forces during the processing of multiphase fibers and particle reinforced polymer matrix composites (MFPRP), it is essential to accurately predict their cutting force. This paper introduces a novel cutting force model for multiphase fibers and particle reinforced polymer matrix composites based on multiphase microstructural characteristics. A series of models are established based on the unique distribution patterns of fiber bundles, particles, and matrix: including models for the matrix and glass particle cutting forces. Simultaneously, cutting force models for microscopic representative volume element (MRVE) are established based on fibers oriented in different directions. The overall cutting force model is derived by incorporating the longitudinal arrangement of materials and tool conditions. Finally, comparing predicted cutting forces with experimental data yields an average error of 6.17%, effectively predicting the magnitude of cutting forces in MFPRP and laying a foundation for cutting force regulation.为了防止多相纤维和颗粒增强聚合物基复合材料(MFPRP)在加工过程中因高切削力而造成过度损坏,必须准确预测其切削力。本文介绍了一种基于多相微结构特征的新型多相纤维和颗粒增强聚合物基复合材料切削力模型。根据纤维束、颗粒和基体的独特分布模式建立了一系列模型,包括基体和玻璃颗粒切削力模型。同时,根据纤维在不同方向的取向,建立了微观代表体积元素(MRVE)的切割力模型。结合材料的纵向排列和工具条件,得出整体切削力模型。最后,将预测的切削力与实验数据进行比较,得出平均误差为 6.17%,从而有效预测了 MFPRP 中的切削力大小,为切削力调节奠定了基础。Construction of interfacial interlocking structure in epoxy composites with enhanced mechanical performance and ultraviolet resistanceYin Yu, Dawei Xu, Qi Wangdoi:10.1016/j.compositesa.2024.108200 在环氧树脂复合材料中构建界面互锁结构,提高机械性能和抗紫外线性能Replacing carbon fibers with organic fibers to reinforce the polymer matrix has become a promising development direction in the preparation of structural composites owing to its low density and cost, but the mechanical performance of organic fibers restricts their further application. Herein, poly(vinyl alcohol) (PVA) fibers were utilized to reinforce the epoxy resin (EP) through the incorporation of zinc oxide nanoparticles (ZnO NPs) in PVA solution (PVAS), and high-strength composite for 122.3 MPa with interfacial interlocking structure was successfully fabricated via vacuum resin transfer molding (VARTM). ZnO NPs were coated on the PVA fibers and enhanced the surface roughness, which improved the mechanical performance of the composite. In comparison with untreated composites, the interlaminar shear strength (ILSS) of composites displayed a significant increase, from 99.4 MPa to 122.3 MPa, resulting from improved interfacial bonding and reduced interfacial gap. Simultaneously, the incorporation of ZnO NPs efficiently enhanced the ultraviolet (UV) resistance.用有机纤维代替碳纤维增强聚合物基体因其密度低、成本低而成为制备结构复合材料的一个有前途的发展方向,但有机纤维的机械性能限制了其进一步应用。本文通过在聚乙烯醇(PVA)溶液(PVAS)中加入氧化锌纳米粒子(ZnO NPs),利用聚乙烯醇(PVA)纤维增强环氧树脂(EP),并通过真空树脂传递模塑(VARTM)成功制备了具有界面交错结构的 122.3 MPa 高强度复合材料。在 PVA 纤维上涂覆 ZnO NPs 提高了表面粗糙度,从而改善了复合材料的机械性能。与未经处理的复合材料相比,复合材料的层间剪切强度(ILSS)有了显著提高,从 99.4 兆帕提高到 122.3 兆帕,这是由于界面粘合力提高和界面间隙减小所致。同时,ZnO NPs 的加入还有效增强了复合材料的抗紫外线(UV)性能。Composites Part B: EngineeringTensile damage evolution and mechanical behaviour of SiCf/SiC mini-composites through 4D in-situ micro-CT and data-driven modellingWeiyu Guo, Daxu Zhang, Yi Zhang, Yonglong Du, Chao Chendoi:10.1016/j.compositesb.2024.111439 通过四维原位显微 CT 和数据驱动建模研究 SiCf/SiC 微型复合材料的拉伸损伤演变和力学性能Damage evolution of SiCf/SiC ceramic matrix mini-composites (CMMCs) was characterised by using a 4D in-situ micro-computed tomography (CT) tensile test and digital volume correlation (DVC) technique. Additionally, a CT damage data-driven shear lag model was developed to predict its tensile stress-strain response. A 4D in-situ X-ray CT tensile test of a unidirectional SiCf/SiC mini-composite was first carried out. Then two ad-hoc deep-learning image segmentation models were developed to automatically identify its microstructure and damages induced by tension, respectively. Damage evolution was quantitively characterised by visualising the initiation and propagation of matrix cracks in three-dimensions (3D). A two-step approach was employed to evaluate its 3D internal strain distributions at various loading levels, which further revealed strain concentrations and helped establishing the tensile stress-strain response of the CMMCs. It was observed that transverse cracking is the predominant damage mode, and the average crack opening displacement increases with loading. A high-fidelity X-ray CT data-driven shear lag model was developed, incorporating inputs of transverse matrix crack spacing calculated by the 4D in-situ CT test data. The predicted stress-strain response showed a good correlation with the experimental results.通过使用四维原位微型计算机断层扫描(CT)拉伸试验和数字体积相关(DVC)技术,对 SiCf/SiC 陶瓷基微型复合材料(CMMC)的损伤演变进行了表征。此外,还开发了一种由 CT 损伤数据驱动的剪切滞后模型,用于预测其拉伸应力-应变响应。首先对单向 SiCf/SiC 微型复合材料进行了四维原位 X 射线 CT 拉伸试验。然后开发了两个临时深度学习图像分割模型,分别用于自动识别其微观结构和拉伸引起的损伤。通过可视化三维(3D)基体裂纹的产生和扩展,对损伤演变进行了定量表征。采用两步法评估了不同加载水平下的三维内部应变分布,进一步揭示了应变集中,有助于确定 CMMC 的拉伸应力应变响应。研究发现,横向开裂是最主要的破坏模式,裂缝张开的平均位移随加载而增加。通过输入由四维原位 CT 测试数据计算得出的横向矩阵裂缝间距,建立了高保真 X 射线 CT 数据驱动的剪切滞后模型。预测的应力-应变响应与实验结果显示出良好的相关性。Composites Science and TechnologyImproving the impact performance of natural fiber reinforced laminate through hybridization and layup designJ.L. Liu, V.N.H. Pham, L. Mencattelli, Enquan Chew, P.Y. Chua, J. Shen, K. Tian, Jie Zhi, D. Jiang, T.E. Tay, V.B.C. Tandoi:10.1016/j.compscitech.2024.110585 通过杂化和铺层设计提高天然纤维增强层压板的冲击性能There is growing interest in Natural Fiber Reinforced Polymer (NFRP) composites for structural components despite their lower mechanical performance than synthetic composites such as Glass Fiber Reinforced Polymer (GFRP) composite. This study demonstrates significant improvement in impact resistance of NFRP-GFRP hybrid laminates can be achieved through the integration of laminate layup design with interlaminar hybridization. By placing more GFRP plies near the top and bottom of the hybrid laminate while reducing the occurrence of neighbouring GFRP-GFRP plies and neighbouring NFRP-NFRP plies around the centre of the laminate, the impact resistance of the hybrid laminate can be significantly improved and even surpass GFRP laminates. On top of stacking sequence of plies, the impact resistance of the hybrid laminates can be further improved by introducing a bio-inspired helicoidal layup. The result shows that with 30 wt.% GFRP plies and 70 wt.% NFRP plies, the perforation energy of NFRP-GFRP hybrid helicoidal laminate outperforms both the plain GFRP and plain NFRP laminates by 11.7% and 143.8%, respectively, whereas the peak load of the hybrid helicoidal laminate subjected to impact is also comparable to the plain GFRP laminate.尽管天然纤维增强聚合物(NFRP)复合材料的机械性能低于玻璃纤维增强聚合物(GFRP)复合材料等合成复合材料,但人们对其结构部件的兴趣与日俱增。本研究表明,通过将层压板铺层设计与层间杂化相结合,可以显著提高 NFRP-GFRP 混合层压板的抗冲击性能。通过在混合层压板的顶部和底部附近放置更多的 GFRP 层,同时减少层压板中心周围相邻的 GFRP-GFRP 层和相邻的 NFRP-NFRP 层,混合层压板的抗冲击性可以得到显著提高,甚至超过 GFRP 层压板。在层压板堆叠顺序的基础上,通过引入生物启发的螺旋形层压,可进一步提高混合层压板的抗冲击性能。结果表明,在 30 重量%的 GFRP 层和 70 重量%的 NFRP 层中,NFRP-GFRP 混合螺旋形层压板的穿孔能分别比普通 GFRP 层压板和普通 NFRP 层压板高出 11.7% 和 143.8%,而混合螺旋形层压板在受到冲击时的峰值载荷也与普通 GFRP 层压板相当。Shape memory polyimide/carbon nanotube composite aerogels with physical and chemical crosslinking architectures for thermal insulating applicationsLiying Zhang, Xiang Li, Enjie Ding, Zhengyu Guo, Chuyang Luo, Hui Zhang, Jianyong Yudoi:10.1016/j.compscitech.2024.110588 用于隔热应用的具有物理和化学交联结构的形状记忆聚酰亚胺/碳纳米管复合气凝胶The development of lightweight smart materials with exceptional shape memory and thermal insulation properties is highly important in the aerospace industry. The reported shape memory polymer aerogels (SMPAs) are restricted to harsh environments because of their poor high-temperature resistance and large volume shrinkage at elevated temperatures. Herein, shape memory polyimide (PI) composite aerogels with superior thermal insulation were fabricated by combining molecularly designed PI chains with amino-functionalized carbon nanotubes (NH2-CNTs) through freezing gelation and subsequent thermal imidization. Because shape memory behavior was thermally triggered, the thermal conductivity associated with the shape memory mechanisms of the aerogels was comprehensively explored. The presence of CNTs promoted heat transfer in the aerogel skeleton, facilitating the shape recovery response. Benefiting from chemical-crosslinked and physical-crosslinked structures, the fabricated PI composite aerogels demonstrated desirable thermo-mechanical properties, exceptional shape memory and superior thermal insulation performance. This study may provide guidelines for designing shape memory PI composite aerogels for harsh environment applications in aerospace engineering.开发具有优异形状记忆和隔热性能的轻质智能材料对航空航天工业非常重要。已报道的形状记忆聚合物气凝胶(SMPAs)因其耐高温性差和在高温下 体积收缩大而仅限于在恶劣环境下使用。在本文中,通过冷冻凝胶化和随后的热酰亚胺化,将分子设计的聚酰亚胺(PI)链与氨基功能化碳纳米管(NH2-CNTs)结合在一起,制造出了具有优异隔热性能的形状记忆聚酰亚胺(PI)复合气凝胶。由于形状记忆行为是由热引发的,因此我们对与气凝胶形状记忆机制相关的导热性进行了全面探索。碳纳米管的存在促进了气凝胶骨架中的热传导,有利于形状恢复反应。得益于化学交联和物理交联结构,所制备的 PI 复合气凝胶表现出理想的热机械性能、优异的形状记忆和卓越的隔热性能。这项研究可为设计用于航空航天工程中恶劣环境应用的形状记忆 PI 复合气凝胶提供指导。来源:复合材料力学仿真Composites FEM

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