【新文速递】2024年1月26日复合材料SCI期刊最新文章
今日更新:Composite Structures 3 篇,Composites Part A: Applied Science and Manufacturing 1 篇,Composites Science and Technology 3 篇
Composite Structures
An analytical approach for characterizing the fracture behaviour of ultra-high-performance fibre reinforced concrete
Bineet Kumar, Awadhesh Sharma, Sonalisa Ray
doi:10.1016/j.compstruct.2024.117922
一种表征超高性能纤维增强混凝土断裂行为的分析方法
The application of ultra-high-performance fibre-reinforced concrete (UHPFRC) offers significant advantages in constructing durable and efficient structural elements due to its remarkable compressive and flexural strength and dense microstructure. However, accurately predicting the hardening/softening profile of UHPFRC in relation to post-cracking tensile behaviour poses challenges, particularly when considering the influence of specimen size. In this work, the post-cracking tensile behaviour has been characterized by considering beam specimens of varying sizes under centre point loading. The inverse analysis approach has been employed to extract relevant information. A polylinear tensile stress profile has been proposed to capture the different fracture mechanisms involved, and an analytical model has been developed to predict the relationship between stress and crack width in the post-cracking zone. Critical crack width and fracture process zone length have been calculated, revealing the substantial contributions of the micro-cracking and fibre-bridging zones to the cohesive zone development in UHPFRC. Furthermore, it has been observed that the microcracking zone diminishes as the specimen size increases, highlighting its significant role in the size effect observed in UHPFRC and similar materials. A modified size effect model has been proposed incorporating the influence of the microcracking zone observed in the UHPFRC composite.
高性能纤维增强混凝土(UHPFRC)由于其显著的抗压和抗弯强度和致密的微观结构,在构建耐用和高效的结构元件方面具有显著的优势。然而,准确预测UHPFRC的硬化/软化曲线与开裂后拉伸行为的关系是一项挑战,特别是在考虑试样尺寸的影响时。在这项工作中,开裂后的拉伸行为的特点是考虑不同尺寸的梁试件在中心点加载。利用逆分析方法提取相关信息。研究人员提出了一个多线性拉伸应力分布图来捕捉不同的断裂机制,并建立了一个分析模型来预测开裂后区域的应力与裂缝宽度之间的关系。计算了临界裂缝宽度和断裂过程区长度,揭示了微裂缝区和纤维桥接区对UHPFRC黏聚带发育的重要贡献。此外,随着试样尺寸的增大,微裂纹区减小,这突出了其在UHPFRC和类似材料中观察到的尺寸效应中的重要作用。提出了一种修正的尺寸效应模型,该模型考虑了UHPFRC复合材料中观察到的微裂纹区对尺寸效应的影响。
Robust, self-healable, recyclable and thermally conductive silicone composite as intelligent thermal interface material
Ziqian Lin, Hao Jin, Haoyu Deng, Zhaoji Zu, Haiqing Huang, Lanyue Zhang, Hongping Xiang
doi:10.1016/j.compstruct.2024.117932
坚固,自愈,可回收和导热硅树脂复合材料作为智能热界面材料
The facile preparation of robust, thermally conductive, self-healable and recyclable silicone composite is still a major challenge, so an asymmetric dynamic crosslinking chain strategy is proposed herein. Due to the better synergy of dynamic covalent and non-covalent bonds, this crosslinked network designed increases the tensile strength of silicone elastomer by 3 times to 5.1 MP, compared to traditional symmetric crosslinking structures (1.7 MPa). Moreover, optimizing the size and content of thermally conductive fillers (Al2O3 and BN), the thermal conductivity of silicone composite reaches 2.9 W/mK, vitalizing the rapid heat conduction and dissipation. Moreover, the composite can be repeatedly self-healed and reprocessed, its tensile strength and thermal conductivity recover 95%. The composite can also be recycled into silicone matrix and fillers, and the recycled materials can be remolded into new composite, allowing the recycling of electronic devices. Therefore, this work opens new avenues for intelligent thermal management in electronic devices.
制备坚固、导热、自愈和可回收的有机硅复合材料仍然是一个重大挑战,因此本文提出了一种不对称动态交联链策略。由于动态共价键和非共价键更好的协同作用,与传统的对称交联结构(1.7 MPa)相比,该交联网络的抗拉强度提高了3倍,达到5.1 MP。通过优化导热填料(Al2O3和BN)的尺寸和含量,有机硅复合材料的导热系数达到2.9 W/mK,有利于材料的快速导热和散热。复合材料可反复自愈和再加工,抗拉强度和导热系数恢复95%。复合材料还可以回收成硅基和填料,回收的材料可以重塑成新的复合材料,允许电子设备的回收利用。因此,这项工作为电子器件的智能热管理开辟了新的途径。
Effects of prestressing wire corrosion on the load response law and bearing capacity of PCCP
Penglong Zhao, Zheng Si, Lingzhi Huang, Yanlong Li
doi:10.1016/j.compstruct.2024.117933
预应力丝腐蚀对PCCP荷载响应规律及承载力的影响
The corrosion of prestressed steel wires plays a crucial role in the failure of prestressed concrete cylinder pipes (PCCP). To explore the load-bearing response of prestressed steel wire corroded PCCP and the impact of prestressed steel wire corrosion on the load-bearing capacity of PCCP, a high-precision finite element model of buried PCCP with prestressed steel wire corrosion was established, and a bearing test was conducted based on this model. The results show that the corrosion of prestressed steel wires has the greatest impact on the mortar protective layer and outer core concrete, and the corrosion point at the waist of the pipe is the most detrimental to the pipeline. In addition, as the degree of corrosion of the steel wire increases, the mortar protective layer and outer core concrete at the corrosion point first crack under the action of compressive stress and internal water pressure. Finally, it was verified that the constructed bearing capacity model of PCCP with different corrosion points had high accuracy and could be used to predict the bearing capacity of corroded pipelines. This article can provide theoretical support for the structural safety monitoring and repair of PCCP in service.
预应力钢丝的腐蚀对预应力混凝土筒管的破坏起着至关重要的作用。为探讨预应力钢丝腐蚀PCCP的承载响应以及预应力钢丝腐蚀对PCCP承载能力的影响,建立了预应力钢丝腐蚀埋地PCCP的高精度有限元模型,并基于该模型进行了承载试验。结果表明,预应力钢丝的腐蚀对砂浆保护层和外芯混凝土的影响最大,管道腰部的腐蚀点对管道的危害最大。此外,随着钢丝腐蚀程度的增加,腐蚀点处的砂浆保护层和外芯混凝土在压应力和内部水压的作用下首先开裂。最后验证了所构建的不同腐蚀点PCCP承载力模型具有较高的精度,可用于预测腐蚀管道的承载力。本文可为在役PCCP结构安全监测与维修提供理论支持。
Composites Part A: Applied Science and Manufacturing
A Progressive micromechanical model for single-polymer composites and experimental validation on self-reinforced PA6-based composites
S.K. Jalali, G. Greco, D. Rigotti, A. Dorigato, H. Mirbaha, G. Fredi, M. Bertolla, S. Guerra, T. Battistini, A. Dal Moro, A. Pegoretti, N.M. Pugno
doi:10.1016/j.compositesa.2024.108042
单高分子复合材料的渐进细观力学模型及自增强pa6基复合材料的实验验证
The current paper proposes a novel analytical micromechanics model to progressively predict the mechanical behavior of composites reinforced by continuous or discontinuous aligned fibers considering the nonlinear mechanical behavior of components and statistical breakage of fiber bundles based on the Curtin model. The PA6-based Single polymer composites (SPCs) are selected and extensive sets of experimental measurements on 12 available PA6 fibers with adequate repetitions to find reliable statistical Weibull parameters are performed. In addition, 10 different PA6 matrix samples, polymerized with various dosages of additives and raw materials, are tested. A remarkable potential for enhancing both strength and toughness of neat PA6 matrix is demonstrated. Results reveal that using tough matrices with elongation in the order of PA6 fibers significantly enhances both strength and toughness of the SPC. The developed progressive micromechanics model provides an analytical parametric framework and a design guideline for developing new recyclable SPCs.
本文在Curtin模型的基础上,考虑构件的非线性力学行为和纤维束的统计断裂,提出了一种新的分析细观力学模型来逐步预测连续或不连续排列纤维增强复合材料的力学行为。选择了PA6基单聚合物复合材料(SPCs),并对12种可用的PA6纤维进行了大量的实验测量,并进行了足够的重复,以找到可靠的统计威布尔参数。此外,测试了10种不同的PA6基质样品,用不同剂量的添加剂和原料聚合。结果表明,纯PA6基体在提高强度和韧性方面具有显著的潜力。结果表明,采用与PA6纤维等次的韧性基体可以显著提高SPC的强度和韧性。所建立的渐进式细观力学模型为开发新型可回收塑料提供了分析参数框架和设计指导。
Composites Science and Technology
Investigation of the mode-I delamination behavior of Double-Double laminate carbon fiber reinforced composite
Menglin Zhao, Yang Zhao, Anyang Wang, Zhengping Chang, Jinyuan Zhang, Zhongqi Wang
doi:10.1016/j.compscitech.2024.110463
双层-双层层合碳纤维增强复合材料i型分层行为研究
Double-Double (DD) laminate, consisting of a repeat of a 4-ply sub-laminate [±Φ/±Ψ], has attracted widespread attention. The delamination damage of composites is always a significant failure problem in the application and a challenge for DD laminate. However, the mode-I delamination propagation behavior and fracture toughness of DD laminate with different interface angles were seldom reported. In this study, the interface angles of DD laminate were variable and could be classified into two types: Ψ/Φ and –Ψ/Φ interfaces. The effect of interface angle on the delamination propagation of DD laminate was explored using the double cantilever beam test. The delamination damage mechanisms of the above interfaces were revealed using macroscopic and microscopic characterization methods. The results showed that the initial fracture toughness values of laminates at the 0°/0°, 90°/0°, Ψ/Φ, and –Ψ/Φ interfaces were similar, and the steady-state fracture toughness values of laminates at the Ψ/Φ interfaces were at least 20 % higher than that of the –Ψ/Φ interfaces. Moreover, the maximum bridging stresses at Ψ/Φ and –Ψ/Φ interfaces were approximately equal, while the final failure displacements at Ψ/Φ interfaces were about 1.4–1.5 times than that at –Ψ/Φ interfaces.
双双层(DD)层压板,由重复的4层亚层压板组成[±Φ/±Ψ],引起了广泛的关注。复合材料的分层损伤一直是复合材料应用中的重要失效问题,也是对DD复合材料的挑战。然而,不同界面角DD层合板的i型分层扩展行为和断裂韧性却鲜有报道。在本研究中,DD层压板的界面角度是可变的,可分为Ψ/Φ和-Ψ /Φ两种界面类型。采用双悬臂梁试验研究了界面角对DD层合板分层扩展的影响。采用宏观和微观表征方法揭示了上述界面的分层损伤机理。结果表明,分层的初始断裂韧性值在0°/ 0°、90°/ 0°,Ψ/Φ——Ψ/Φ接口类似,稳态的分层断裂韧性值Ψ/Φ接口至少20 %高于-Ψ/Φ接口。此外,Ψ/Φ和-Ψ /Φ界面的最大桥接应力近似相等,而Ψ/Φ界面的最终破坏位移约为-Ψ /Φ界面的1.4 ~ 1.5倍。
Predicting the material behavior of recycled composites: Experimental analysis and deep learning hybrid approach
Yoon-Bo Shim, In Yong Lee, Young-Bin Park
doi:10.1016/j.compscitech.2024.110464
预测再生复合材料的材料行为:实验分析和深度学习混合方法
The end-of-life issues associated with composite materials have inspired extensive investigations into recycling methods. However, recycled composites cannot be widely used owing to their poor reliability, which is caused by the random and significant variations in their mechanical properties. This accordingly study proposed and demonstrated a method for predicting the mechanical behaviors and fracture mechanisms of recycled composites. First, recycled carbon-fiber-reinforced polymers were manufactured using mechanical recycling and compression molding. Surface images of the resulting specimens were captured and tension tests subsequently conducted to obtain their mechanical properties. The images and test results were used to train convolutional neural networks to predict three mechanical properties and investigate the resulting stress–strain curves. Furthermore, the specimen fracture mechanisms were investigated using the Gradient-weighted Class Activation Mapping technique. The results indicate that the proposed approach can be effectively applied to analyze the mechanical behaviors of recycled composites and provide insights into their fracture mechanisms under specific stress conditions. These capabilities are expected to increase the reliability and utility of recycled composite materials.
与复合材料相关的寿命终结问题激发了对回收方法的广泛调查。然而,再生复合材料的可靠性较差,这是由于其力学性能的随机和显著变化造成的。本研究提出并展示了一种预测再生复合材料力学行为和断裂机制的方法。首先,利用机械回收和压缩成型制造再生碳纤维增强聚合物。捕获所得试样的表面图像,随后进行张力试验以获得其机械性能。利用图像和测试结果训练卷积神经网络来预测三种力学性能,并研究得到的应力-应变曲线。此外,使用梯度加权类激活映射技术研究了试样的断裂机制。结果表明,该方法可以有效地用于分析再生复合材料的力学行为,并对其在特定应力条件下的断裂机制提供深入的了解。这些能力有望提高回收复合材料的可靠性和实用性。
Assessing pseudo-ductile behavior of woven thermoplastic composites under tension and bending
Himayat Ullah, Rafi Ullah Khan, Vadim V. Silberschmidt
doi:10.1016/j.compscitech.2024.110465
织物热塑性复合材料在拉伸和弯曲作用下的伪延性评估
Most fiber-reinforced composites are inherently brittle and fail suddenly at low strains without yielding and energy-absorbing capability. Still, under some conditions, they can demonstrate ductile like response known as pseudo-ductility. To investigate such a response, experimental analysis of carbon- and glass-fabric reinforced thermoplastic polymer (C/GFRP) composites was performed in on- and off-axis orientations under service loading conditions of tension and bending. Tensile tests of off-axis specimens were conducted with a full-field strain-measurement digital image correlation (DIC) technique. Cyclic bending tests of on- and off-axis C/GFRP specimens were performed to assess their ductility and damage behavior. The tests revealed that on-axis CFRP laminates failed due to fracture of brittle carbon fibers under tension, monotonic and cyclic bending. The on-axis GFRP samples demonstrated a linear-elastic brittle response under tension but a visco-elasto-plastic nonlinear behavior under monotonic and cyclic bending with hysteresis and energy absorption. The off-axis C/GFRP specimens exhibited ductile behavior akin to metals, enduring high strains with permanent deformation before ultimate failure, and absorbing substantial amounts of energy. The pseudo-ductile response of off-axis CFRP specimens under bending can be attributed to plasticity and damage of matrix as well as fiber trellising, whereas in the on-axis GFRP specimens, it is primarily due to visco-elasto-plastic behavior of glass fibers and the TPU matrix. It is concluded that material's response can be tailored for stiffness, strength and ductility for specific applications.
大多数纤维增强复合材料具有固有的脆性,在低应变下突然失效,没有屈服和吸能能力。然而,在某些条件下,它们可以表现出类似延性的反应,即所谓的伪延性。为了研究这种响应,对碳纤维和玻璃纤维增强热塑性聚合物(C/GFRP)复合材料在轴向和离轴方向上进行了拉伸和弯曲载荷条件下的实验分析。采用全场应变测量数字图像相关(DIC)技术对离轴试件进行拉伸试验。对C/GFRP在轴和离轴试件进行了循环弯曲试验,以评估其延性和损伤行为。试验结果表明,轴向碳纤维复合材料层合板在拉伸、单调弯曲和循环弯曲作用下脆性碳纤维断裂而失效。轴向GFRP试样在拉伸作用下表现为线弹性脆性响应,而在单调和循环弯曲作用下表现为粘弹塑性非线性响应,并存在滞回和能量吸收。离轴C/GFRP试件表现出类似金属的延性行为,在最终破坏前承受高应变和永久变形,并吸收大量能量。离轴CFRP试件在弯曲作用下的拟延性响应可归因于基体的塑性、损伤以及纤维格架,而对轴GFRP试件的拟延性响应主要是由于玻璃纤维和TPU基体的粘弹塑性行为。得出的结论是,材料的响应可以根据特定应用的刚度,强度和延性进行定制。
