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【新文速递】2024年6月17日复合材料SCI期刊最新文章

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

Composite Structures

Novel interaction effects enhance specific energy absorption in foam-filled CFRP tapered tubes

Xinmei Xiang, Chenkun Xiao, Guoxing Lu, Yi Min Xie, Haiyang Yang, Jing Zhang, Ngoc San Ha

doi:10.1016/j.compstruct.2024.118288

新颖的相互作用效应增强了泡沫填充 CFRP 锥形管的比能量吸收能力

This study unveils a novel interaction effect in the foam-filled CFRP tapered tubes that enhances their specific energy absorption (SEA), challenging the conventional understanding that foam fillers decrease the SEA of structures like foam-filled CFRP straight tubes and foam-filled metal tapered tubes. Quasi-static axial compression tests were conducted on foam-filled CFRP tubes with varying taper angles (0°, 5°, 10°, 15°) to confirm and quantify this newfound interaction effect. The energy absorption characteristics and interaction effect due to the foam filler in the foam-filled CFRP tapered tubes were thoroughly evaluated and compared to 3D-printed 316L stainless steel tubes and unfilled CFRP counterparts. Contrary to expectations, our results indicate that the foam-filled CFRP tubes consistently outperform both steel and unfilled CFRP tubes in energy absorption. Intriguingly, the CFRP foam-filled tapered tubes in this study demonstrated higher SEA compared to CFRP tubes without foam filler, underscoring the remarkable effectiveness of CFRP materials in foam-filled tapered tube applications. Our comprehensive interaction effect analysis highlights the substantial contribution of the unique synergy between the foam filler and the debris of the CFRP tapered tube to this increased SEA. Additionally, we propose a novel hybrid design that integrates straight and tapered CFRP tubes with foam fillers, leveraging the newfound interaction effect to further enhance the energy absorption of tapered tubes. This research not only emphasizes the advantages of foam fillers in enhancing CFRP tapered structures but also introduces innovative possibilities for energy absorption applications across various industries.

本研究揭示了泡沫填充 CFRP 锥形管中的新型相互作用效应,这种效应可增强其比能量吸收(SEA),从而挑战了泡沫填充物会降低泡沫填充 CFRP 直管和泡沫填充金属锥形管等结构的 SEA 的传统认识。我们对不同锥角(0°、5°、10°、15°)的泡沫填充 CFRP 管进行了准静态轴向压缩试验,以确认和量化这种新发现的相互作用效应。对泡沫填充的 CFRP 锥形管的能量吸收特性和泡沫填充物的相互作用效应进行了全面评估,并与 3D 打印的 316L 不锈钢管和未填充的 CFRP 管进行了比较。与预期相反,我们的结果表明,填充泡沫的 CFRP 管在能量吸收方面始终优于钢管和未填充的 CFRP 管。耐人寻味的是,与未填充泡沫的 CFRP 管相比,本研究中填充泡沫的 CFRP 锥形管具有更高的 SEA 值,这表明 CFRP 材料在填充泡沫的锥形管应用中效果显著。我们进行了全面的相互作用效应分析,结果表明,泡沫填充物与 CFRP 锥形管碎片之间的独特协同作用对 SEA 的提高做出了重大贡献。此外,我们还提出了一种新型混合设计,将带有泡沫填料的直管和锥形 CFRP 管整合在一起,利用新发现的相互作用效应进一步提高锥形管的能量吸收能力。这项研究不仅强调了泡沫填料在增强 CFRP 锥形结构方面的优势,还为各行各业的能量吸收应用带来了创新的可能性。


Composites Part A: Applied Science and Manufacturing

Advances in bulk TiB2-based composites: Densification and toughening

Zhennan Cao, Jialin Sun, Keguo Zhang, Wenbin Ji, Kunlong Cai, Bin Li, Bo Liu, Chengqiang Fan

doi:10.1016/j.compositesa.2024.108318

块状 TiB2 基复合材料的进展:致密化和增韧

TiB2 based materials have attracted extensive attention due to its considerable hardness and elastic modulus, excellent wear/ corrosion resistance as well as exceptional electrical/ thermal conductivity. The potential structural and functional applications of TiB2 based materials include reentry vehicles, cutting tools, thermal insulation boards, new energy batteries, ballistic protection high temperature nuclear reactors. However, the poor densification together with inferior fracture toughness dramatically limited the practical application of TiB2. Herein, we critically survey, summarize, and discuss the recent advances on preparation and mechanical properties of TiB2-based materials, focusing on the current understanding of densification and toughening strategies and mechanisms. Borrowing the concept of cemented carbide, cemented TiB2 is proposed in this review, highlighting the different binder phase on improving the densification of TiB2, including metal, intermetallic, ceramic and high entropy alloy. Subsequently, through discussing the factors influencing the efficiency of toughening TiB2, we determine and compare various toughening approaches on TiB2. Furthermore, the challenges and prospects of high performance TiB2 for future scientific researches and practical possibilities are also briefly summarized. We believe a thorough summary of the densification and toughening mechanisms will significantly contribute to the development of dense, strong and tough TiB2 materials in a much more efficient way, advancing them for further wide applications.

由于 TiB2 具有相当高的硬度和弹性模量、出色的耐磨性/耐腐蚀性以及优异的导电性/导热性,它已引起了广泛的关注。基于 TiB2 的材料在结构和功能方面的潜在应用包括重返大气层飞行器、切削工具、隔热板、新能源电池、防弹高温核反应堆。然而,较差的致密性和较差的断裂韧性极大地限制了 TiB2 的实际应用。在此,我们对基于 TiB2 的材料的制备和机械性能的最新进展进行了批判性的调查、总结和讨论,重点是目前对致密化和增韧策略及机制的理解。借用硬质合金的概念,本综述提出了硬质合金 TiB2,强调了不同粘结相对改善 TiB2 变质的作用,包括金属、金属间、陶瓷和高熵合金。随后,通过讨论影响 TiB2 增韧效率的因素,我们确定并比较了 TiB2 的各种增韧方法。此外,我们还简要总结了高性能 TiB2 在未来科学研究和实用可能性方面所面临的挑战和前景。我们相信,对致密化和增韧机理的全面总结将极大地促进以更高效的方式开发致密、高强度和高韧性的 TiB2 材料,推动其进一步广泛应用。


Composites Part B: Engineering

Rational structure design of metal-based cathode for high-rate and long-cycling sodium nickel chloride batteries

Guowei Xiong, Xiangwei Wu, Zhaoyin Wen

doi:10.1016/j.compositesb.2024.111636

用于高倍率和长循环氯化钠镍电池的金属基正极的合理结构设计

High-temperature sodium-nickel chloride (Na-NiCl2) batteries represented as an advanced energy storage technology show impressive advantages including abundant raw materials, high safety and long-cycling life. Nevertheless, their large-scale application is still hindered by the poor stability and rate capability of the cathode. In this work, we designed a three-dimensional cross-linked network composed of NiFe alloy nanowires via a magnetic-field assisted method. The as-prepared NiFe nanowires (NiFe NWs) are mixed with NaCl as the composite cathode of sodium-metal chloride batteries, delivering exceptionally enhanced rate performance (150.3 mAh/g@0.88 C) and superior cycling stability (84.3% capacity retention after 500 cycles). The properties are superior to those of the cathode based on the pristine Ni nanowires or the NiFe nanoparticles, which is ascribe to the existence of active Fe metal and the continuous conductive network, as confirmed by kinetics analysis. After experiencing a long-term cycling at large current density (∼0.88 C), no obvious coarsening of NiFe NWs and NaCl particles occurs. Moreover, the large-size Na-NiCl2 battery with capacity of 229 mAh reaches a practical energy density of 265.65 Wh kg−1 (∼0.3 C) with energy efficiency of 88.6%. Therefore, our work provides a guide for rational design of cathode structure, thereby improving rate and cycling performance of Na-NiCl2 batteries.

高温氯化钠镍(Na-NiCl2)电池作为一种先进的储能技术,具有原料丰富、安全性高、循环寿命长等显著优势。然而,其大规模应用仍然受到阴极稳定性和速率能力差的阻碍。在这项研究中,我们通过磁场辅助方法设计了一种由镍铁合金纳米线组成的三维交联网络。制备的镍铁合金纳米线(NiFe NWs)与氯化钠(NaCl)混合后用作氯化钠金属电池的复合阴极,可显著提高速率性能(150.3 mAh/g@0.88 C)和循环稳定性(500 次循环后容量保持率为 84.3%)。其性能优于基于原始镍纳米线或镍铁纳米颗粒的阴极,这归功于活性铁金属的存在和连续的导电网络,这一点已通过动力学分析得到证实。在大电流密度(∼0.88 C)下长期循环后,镍铁纳米线和氯化钠颗粒没有发生明显的粗化现象。此外,容量为 229 mAh 的大尺寸 Na-NiCl2 电池的实用能量密度达到 265.65 Wh kg-1 (∼0.3 C),能量效率为 88.6%。因此,我们的工作为合理设计正极结构提供了指导,从而提高了 Na-NiCl2 电池的速率和循环性能。


Composites Science and Technology

Experimental and numerical evaluation of the influence of voids on sound absorption behaviors of 3D printed continuous flax fiber reinforced PLA composites

Zhixiong Bi, Qian Li, Zhen Zhang, Zhongsen Zhang, Weidong Yang, Yan Li

doi:10.1016/j.compscitech.2024.110720

 

空隙对 3D 打印连续亚麻纤维增强聚乳酸复合材料吸声行为影响的实验和数值评估

This study aims to quantitatively analyze the effects of voids on sound absorption properties of 3D printed continuous flax fiber reinforced PLA composites (CFFRCs). Three kinds of flax yarns with different linear density were employed to prepare CFFRCs via 3D printing technology. The sound absorption performances of these composites were measured using the impedance tube based on the two-microphone transfer function method. The microstructure morphologies including cross-sections of flax yarns, voids shape and distributions of the composites were observed via ultra-depth microscope and micro-computed tomography to reconstruct the exact structures in simulation. Mercury intrusion porosimetry was applied to measure the voids dimensions of CFFRCs. The influence of voids on sound absorption mechanisms of CFFRCs were revealed based on thermoviscous acoustics theory by conducting the simulation in COMSOL software. The experimental results demonstrated that CFFRCs exhibited excellent sound absorption coefficients (close to 1) within the frequency range of 150 to 350 Hz and 350 to 550 Hz, resulting from the voids inside and between the flax yarns respectively. With the increase of linear density (diameter of the yarn), the contents of voids inside and between the flax yarns both increased. The dimensions of voids inside the flax yarns improved while those between flax yarns remained unchanged. The existence of the voids between the flax yarns resulted in a decrease in the sound absorption coefficient of CFFRCs, while more voids inside flax yarns led to the increase of the sound absorption frequency. Numerical results indicated that voids between the flax yarns contributed to a more uniform change in sound speed, reducing sound absorption performance. Whereas, voids inside the flax yarns could improve viscous friction of soundwaves due to narrow structures, enhancing sound absorption capabilities. This study is anticipated to provide a guidance for the design of integration of structure and function of 3D printed CFFRCs.

本研究旨在定量分析空隙对三维打印连续亚麻纤维增强聚乳酸复合材料(CFFRC)吸声性能的影响。研究采用三种不同线密度的亚麻纱线,通过三维打印技术制备 CFFRC。利用基于双传声器传递函数法的阻抗管测量了这些复合材料的吸声性能。通过超深显微镜和微型计算机断层扫描观察了复合材料的微观结构形态,包括亚麻纱的横截面、空隙形状和分布,从而在模拟中重建了确切的结构。汞侵入孔隙模拟法用于测量 CFFRC 的空隙尺寸。通过在 COMSOL 软件中进行模拟,基于热粘声学理论揭示了空隙对 CFFRC 吸声机制的影响。实验结果表明,CFFRC 在 150 至 350 Hz 和 350 至 550 Hz 频率范围内表现出优异的吸声系数(接近 1),这分别是由于亚麻纱内部和亚麻纱之间的空隙造成的。随着线性密度(纱线直径)的增加,亚麻纱线内部和纱线之间的空隙含量都有所增加。亚麻纱内部空隙的尺寸有所改善,而亚麻纱之间空隙的尺寸保持不变。亚麻纱之间空隙的存在导致 CFFRC 的吸声系数降低,而亚麻纱内部空隙的增加则导致吸声频率增加。数值结果表明,亚麻纱之间的空隙会使声速变化更加均匀,从而降低吸音性能。而亚麻纱线内部的空隙由于结构狭窄,可以改善声波的粘性摩擦,从而提高吸音能力。这项研究有望为三维打印 CFFRC 的结构与功能一体化设计提供指导。



来源:复合材料力学仿真Composites FEM
ACTMechanicalMAGNETComsol断裂复合材料Acoustics新能源声学理论材料储能试验
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首次发布时间:2024-11-21
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【新文速递】2024年6月1日固体力学SCI期刊最新文章

今日更新:International Journal of Solids and Structures 1 篇,Journal of the Mechanics and Physics of Solids 3 篇,International Journal of Plasticity 1 篇,Thin-Walled Structures 3 篇International Journal of Solids and StructuresMachine learning predictions on the compressive stress–strain response of lattice-based metamaterialsLijun Xiao, Gaoquan Shi, Weidong Songdoi:10.1016/j.ijsolstr.2024.112893格基超材料压缩应力-应变响应的机器学习预测Predicting the stress–strain curve of lattice-based metamaterials is crucial for their design and application. However, the complex nonlinear relationship between the mesoscopic structure of lattice materials and their macroscopic mechanical behavior makes prediction challenging. In this study, beam element models of over 20,000 lattice structures were established using Python scripts, and calculations were performed in ABAQUS to obtain training and testing datasets. The spatial features of each lattice-based metamaterial were then encoded into a graph, a data structure recognizable by machine learning algorithm. Utilizing machine learning methods, a Structure to Sequence Neural Network was constructed and trained, achieving rapid prediction of the compressive stress–strain curves for lattice-based metamaterials. Afterwards, several lattice structures were randomly selected and 3D printed. The accuracy of the simulation results as well as machine learning predictions was validated through quasi-static compression experiments. It is revealed that the proposed Neural Network model outperforms the traditional Artificial Neural Networks as the errors are reduced while the Coefficient of Determination is higher. The results demonstrate the accurate fitting between the complex spatial features of the lattice-based metamaterials and their stress–strain curves, which provides a potential methodology for inverse optimization of the lattice-based metamaterials in the future.预测晶格基超材料的应力应变曲线对其设计和应用至关重要。然而,晶格材料的介观结构与其宏观力学行为之间复杂的非线性关系使得预测具有挑战性。在本研究中,使用Python脚本建立了20000多个点阵结构的梁单元模型,并在ABAQUS中进行计算,获得训练和测试数据集。然后将每个基于晶格的超材料的空间特征编码成图,这是一种由机器学习算法可识别的数据结构。利用机器学习方法,构建并训练了结构到序列的神经网络,实现了晶格基超材料压缩应力-应变曲线的快速预测。然后,随机选择几个点阵结构进行3D打印。通过准静态压缩实验验证了仿真结果和机器学习预测的准确性。结果表明,该神经网络模型在误差减小的同时具有较高的决定系数,优于传统的人工神经网络。结果表明,晶格基超材料的复杂空间特征与其应力应变曲线之间具有较好的拟合性,为未来晶格基超材料的逆优化提供了一种潜在的方法。Journal of the Mechanics and Physics of SolidsMechanics of gradient nanostructured metalsYin Zhang, Zhao Cheng, Ting Zhu, Lei Ludoi:10.1016/j.jmps.2024.105719梯度纳米结构金属的力学The emergence of heterogeneous nanostructured materials (HNMs) offers exciting opportunities to achieve outstanding mechanical properties. Among these materials, gradient nanotwinned (GNT) Cu is a prominent class of HNMs, demonstrating superior strengths by gaining extra strengths compared to non-gradient counterparts. Its layered gradient structure provides a simplified quasi-one-dimensional model system for understanding the extra strengthening effects of structural gradients and resulting plastic strain gradients. This paper presents a comprehensive report for recent experimental and modeling studies on the mechanics of GNT Cu, covering advances in controlled material processing, back stress measurement, deformation field characterization, dislocation microstructure analysis, and strain gradient plasticity modeling. These studies unveil the spatiotemporal evolution of both plastic strain gradients and extra back stresses originating from structural gradients. Direct connections are established between the sample-level extra strength of GNT Cu and the synergistic strengthening effects induced by local nanotwin structures and their gradients. We emphasize the critical role of the representative volume element size in assessing the effects of plastic strain gradient and extra back stress. Moreover, lower-order strain gradient plasticity models are validated through experimental characterizations of GNT Cu, paving the way for future investigation into the mechanics of gradient nanostructured metals. Finally, we provide an outlook on research needs for understanding the mechanics of gradient nanostructured metals and, more broadly, HNMs, towards achieving exceptional mechanical properties.非均相纳米结构材料(HNMs)的出现为实现优异的机械性能提供了令人兴奋的机会。在这些材料中,梯度纳米孪晶(GNT) Cu是一类突出的hnm,与非梯度材料相比,通过获得额外的强度,显示出优越的优势。它的分层梯度结构为理解结构梯度和由此产生的塑性应变梯度的额外强化效应提供了一个简化的准一维模型系统。本文介绍了近年来GNT Cu力学的实验和模型研究的综合报告,涵盖了受控材料加工,背应力测量,变形场表征,位错微观结构分析和应变梯度塑性建模的进展。这些研究揭示了塑性应变梯度和由结构梯度引起的额外背应力的时空演变。建立了GNT Cu的样品级额外强度与局部纳米孪晶结构及其梯度引起的协同强化效应之间的直接联系。我们强调了代表性体积单元尺寸在评估塑性应变梯度和额外背应力影响中的关键作用。此外,通过GNT Cu的实验表征验证了低阶应变梯度塑性模型,为进一步研究梯度纳米结构金属的力学奠定了基础。最后,我们展望了研究需求,以了解梯度纳米结构金属的力学,更广泛地说,hnm,以实现卓越的力学性能。Fatigue-resistant adhesion through high energy barriersQi Li, Chao Ma, Yunfeng He, Pengyu Lv, Huiling Duan, Wei Hongdoi:10.1016/j.jmps.2024.105722通过高能量垒抗疲劳粘附The applications of soft materials in various fields often require interfacial adhesion to sustain prolonged static or cyclic loads, whereas most existing adhesives are susceptible to fatigue failure. Unlike in a quasistatic debonding process, which depends more on the average resistance, the key to preventing fatigue crack propagation is to build up high energy barriers locally. Herein, we invoke three types of structural designs to induce large energy barriers at the interface to achieve fatigue-resistant adhesion. By varying the local bending stiffness of the backing layer, locally altering the fracture mode through kirigami patterns, or hindering crack initiation with simple edge notches, we enhanced the fatigue thresholds of various adhesives against peeling by several orders of magnitude, reaching record-breaking values. To verify the proposed mechanism and reveal the details of these remarkable enhancements, we develop theoretical models to study the peeling processes. Based entirely on structural design, the proposed mechanism is non-material-specific and universally applicable to various intermolecular interactions under any harsh environment, such as high temperature, high humidity, and physiological environments. We envision that the strategy and methodologies presented can pave the avenue of future adhesion designs for both durability and reliability.软材料在各个领域的应用通常需要界面粘合来承受长时间的静态或循环载荷,而大多数现有的粘合剂容易疲劳失效。与准静态脱粘过程不同,该过程更多地依赖于平均阻力,而防止疲劳裂纹扩展的关键是在局部建立高能量屏障。在此,我们采用三种类型的结构设计来诱导界面处的大能量障碍以实现抗疲劳粘附。通过改变衬底层的局部弯曲刚度,通过基利格米图案局部改变断裂模式,或通过简单的边缘缺口阻碍裂纹的起裂,我们将各种粘合剂抗剥落的疲劳阈值提高了几个数量级,达到了破纪录的值。为了验证所提出的机制并揭示这些显著增强的细节,我们开发了理论模型来研究剥离过程。该机制完全基于结构设计,非材料特异性,普遍适用于任何恶劣环境下的各种分子间相互作用,如高温、高湿和生理环境。我们设想,所提出的策略和方法可以为未来的耐久性和可靠性粘合设计铺平道路。Bending Stiffness of Ionically Bonded Mica Multilayers told by its BubblesBaowen Li, Wang Tan, Chun Shen, Yuyang Long, Zhida Gao, Jiajun Wang, Wanlin Guo, Jun Yindoi:10.1016/j.jmps.2024.105723离子键合云母多层膜的弯曲刚度由其气泡决定Revealing the bending stiffness of layered materials is crucial for guiding their applications with notable out-of-plane deformation, such as in flexible electronics. To this end, dedicated methods have been developed, but usually involving precise manipulation of atomically thin flakes or cross-section characterization with atomic resolution, hindering their widespread adoption. Here, we utilize mica as a case study to demonstrate that bubbles spontaneously formed during mechanical exfoliation provide a facile but reliable approach for investigating its bending mechanics. Through topographical analysis of bubbles with widely distributed sizes, a bending stiffness is extracted following a nonlinear plate theory. The less bending stiffness than the ideal non-linear plate solution indicates a moderate interlayer slip, as confirmed by molecular dynamics simulations. The interlayer shear coefficient for mica is higher than that for multilayer graphene, which is attributed to its strong interfacial shear strength inheriting from its interlayer ionic bonding.揭示层状材料的弯曲刚度对于指导其在柔性电子等具有显着面外变形的应用至关重要。为此,已经开发了专门的方法,但通常涉及原子薄片的精确操作或原子分辨率的截面表征,阻碍了它们的广泛采用。在这里,我们以云母为例研究,证明在机械剥离过程中自发形成的气泡为研究其弯曲力学提供了一种简单而可靠的方法。通过对尺寸分布广泛的气泡进行形貌分析,根据非线性板理论提取了气泡的弯曲刚度。分子动力学模拟证实,与理想的非线性板溶液相比,弯曲刚度较小表明层间滑移适中。云母的层间剪切系数高于多层石墨烯,这是由于其层间离子键继承了较强的界面剪切强度。International Journal of PlasticityTuning generalized planar fault energies to enable deformation twinning in nanocrystalline aluminum alloysJingfan Zhang, Xueyong Pang, Yue Li, Shaolou Wei, Chao Yang, Shuaihang Pan, Binhan Sun, Dengshan Zhou, Xiaoxu Huang, Deliang Zhang, Gaowu Qindoi:10.1016/j.ijplas.2024.104018调整广义平面断层能使纳米晶铝合金变形孪晶As deformation twins have a profound impact on the plastic flow and mechanical properties of metallic materials, enhancing deformation twinning in face-centered cubic (FCC) metallic materials has long served as a unique microstructure design strategy to attain an extraordinary strength-ductility synergy. Deformation twinning, however, rarely occurs in pure FCC Al and its alloys since its generalized planar fault energies (GPFEs) are almost unaffected by most soluble alloying elements such as Mg, Zn and Cu. Here we successfully tune the GPFEs of a nanocrystalline Al-Mg alloy by alloying with Zr, Fe or Y element, and enable deformation twinning in the Zr-, Fe- and Y-containing alloys. Based on a combined analysis of microscopic observations, modeling and ab initio calculations, we find a strong grain-size-dependent twinning (i.e., twinning occurs in preferable grains having sizes in the range ∼20-40 nm), as well as only one single twinning plane (i.e., twinning occurs in single, parallel atomic planes) for twin formation rather than intersecting twinning planes (i.e., twinning occurs in multiple, unparallel atomic planes) usually observed in coarse-grained FCC materials. This interesting twinning behavior is further observed to be accompanied by grain rotations, producing defective twin boundaries. Our experimental results extend the current understanding of the plastic deformation mechanisms in nanograined metallic materials, and will guide microstructure design of twinnable nanograined Al alloys with an improved strength-ductility synergy.变形孪晶对金属材料的塑性流动和力学性能有着深远的影响,增强面心立方(FCC)金属材料的变形孪晶一直是一种独特的微结构设计策略,以获得非凡的强度-塑性协同效应。变形孪晶在纯FCC Al及其合金中很少发生,因为其广义平面断层能(gpfe)几乎不受大多数可溶合金元素(Mg、Zn和Cu)的影响。在这里,我们成功地通过与Zr、Fe或Y元素合金化来调整纳米晶Al-Mg合金的GPFEs,并使含Zr、Fe和Y的合金发生变形孪晶。基于微观观察、建模和重新计算的综合分析,我们发现了一种强烈的晶粒尺寸依赖的孪晶(即,孪晶发生在尺寸在~ 20-40 nm范围内的优选晶粒中),并且在粗粒FCC材料中通常观察到的孪晶形成只有一个单一的孪晶平面(即,孪晶发生在单个平行的原子平面中),而不是相交的孪晶平面(即,孪晶发生在多个不平行的原子平面中)。这种有趣的孪晶行为进一步观察到伴随着晶粒旋转,产生缺陷孪晶边界。我们的实验结果扩展了目前对纳米金属材料塑性变形机制的理解,并将指导具有改进强度-塑性协同作用的可孪晶纳米铝合金的微观结构设计。Thin-Walled StructuresIsogeometric material optimization for shape control of bi-directional functionally graded plates with piezoelectric layersLiangliang Ma, Chao Wang, Yun Chong, Wenfeng Hu, Lei Zengdoi:10.1016/j.tws.2024.112067压电层双向功能梯度板形状控制的等几何材料优化This paper proposes an effective numerical method for shape control of bi-directional functionally graded plates (2D-FGPs) with piezoelectric layers. Isogeometric analysis (IGA) based on non-uniform rational B-splines (NURBS) related to third-order shear deformation theory (TSDT) is employed for the static analysis of the 2D-FGPs with piezoelectric layers. The B-spline basis functions are utilized to represent the distribution of the ceramic volume fractions, where the control points placed along the plane corresponding to the ceramic volume fraction and the applied voltages are taken as the design variables. In addition, an improved moth flame optimization algorithm is utilized to solve the optimization problem of minimizing the static shape error, which effectively balances the exploratory and exploitative capabilities of the algorithm. Various numerical examples of square, skew, and dart-shaped 2D-FGPs are analyzed to validate the proposed method and demonstrated the superior mechanical performance of 2D-FGPs over 1D-FGPs.提出了一种有效的具有压电层的双向功能梯度板形状控制的数值方法。采用基于非均匀有理b样条(NURBS)和三阶剪切变形理论(TSDT)的等几何分析(IGA)方法对具有压电层的二维fgps进行了静力分析。采用b样条基函数表示陶瓷体积分数的分布,其中以陶瓷体积分数所对应的平面控制点和外加电压为设计变量。此外,利用改进的蛾焰优化算法解决了静态形状误差最小化的优化问题,有效地平衡了算法的探索性和开发性。通过对方形、斜形和镖形2D-FGPs的数值分析,验证了该方法的有效性,并证明了2D-FGPs比1D-FGPs具有更好的力学性能。Dynamic modeling and vibration suppression evaluation of composite honeycomb hemispherical shell with functional gradient protective coatingHui Li, Jichuan Cao, Jintong Han, Jinghan Li, Yao Yangdoi:10.1016/j.tws.2024.112066功能梯度防护涂层复合材料蜂窝半球形壳动力学建模及抑振评价The vibration reduction performance of composite honeycomb hemispherical shells (CHHSs) coated with functional gradient protection coating (FGPC) are investigated in this work. Using the first-order shear deformation theory and the power-law distribution rule, the virtual spring technique, the regional decomposition method, and the Newmark-Beta approach, etc., a dynamic model of the FGPC-CHHSs under base excitation is formulated to solve the inherent characteristics and displacement responses in time and frequency domains. After a set of convergence analyses are completed to ascertain an appropriate segment number and the stiffness values of virtual springs employed in the predictive model, the forecasted vibration parameters are verified using the literature and experimental results that are performed on uncoated and coated shells. The maximal natural frequency errors of the current model compared to the experimental results are 3.8 % and 4.8 %, and the displacement response errors under different excitation amplitudes are less than 10.3 % and 12.7 %, respectively, which demonstrate the correctness of such a model. Finally, the impact of key structural and material parameters on the vibration behaviors of the FPGC-CHHSs is evaluated. To improve their vibration suppression capability, it is recommended to choose a high gradient index of coating material and a large thickness ratio of the FGPC to the overall shell with a reasonable moduli ratio of Material A to Material B of the FGPC to improve vibration reduction capability. This study offers a practical model tool and several important design recommendations for vibration prediction and dynamic attenuation of honeycomb sandwich hemispherical shell structures in aerospace engineering.研究了涂覆功能梯度防护涂层(FGPC)的复合材料蜂窝半球形壳(chhs)的减振性能。利用一阶剪切变形理论和幂律分布规律、虚拟弹簧技术、区域分解法、Newmark-Beta方法等,建立了基础激励下fgpc - chhs的动力学模型,求解了其固有特性和时频域位移响应。在完成一组收敛分析以确定预测模型中使用的虚拟弹簧的适当段数和刚度值之后,使用文献和在未涂覆和涂覆壳体上进行的实验结果验证了预测的振动参数。与实验结果相比,当前模型的最大固有频率误差为3.8%和4.8%,不同激励幅值下的位移响应误差分别小于10.3%和12.7%,证明了该模型的正确性。最后,分析了关键结构参数和材料参数对fpga - chhs振动性能的影响。为了提高其减振能力,建议选择高梯度指数的涂层材料和大的FGPC与总壳的厚度比,以及合理的FGPC材料a与材料B的模量比,以提高其减振能力。该研究为航空航天工程中蜂窝夹层半球形壳结构的振动预测和动力衰减提供了实用的模型工具和一些重要的设计建议。Design of thick-panel origami-inspired deployable protective shields for spacecraftXiaozhao Zhang, Chengjun Gao, Wujun Chen, Tianyang Yang, Shaochen Yang, Guangqiang Fangdoi:10.1016/j.tws.2024.112069 航天器厚板折纸式可展开防护罩设计In recent years, as space is being explored more frequently, various spacecraft have been launched into space. Space debris and radiation in the universe as well as the irregular activities of the sun, such as solar flares and solar storms, can have serious effects on spacecraft. Protective shields are a favorable measure to protect spacecraft from space debris, radiation, and other damage. In this study, a protective shield for spacecraft is first proposed inspired by the behavior of mollusks. The concept of origami is then introduced for the folding and unfolding scheme design. The protective shield has a certain thickness, although its thickness is not significant and can be considered a thin-walled structure, it cannot be treated as zero-thickness origami since even a small thickness can cause issues such as motion interference. This study proposes three guidelines for thickening panels. Through the derivation of spatial geometry, a method to make the spatial curved surface thickening is presented. This method perfectly solves the compatibility problem of vertices in thickening, while making each panel manufacturable. After that, based on space vectors, a computational method for determining whether motion interference occurs in thick-panel curved origami is proposed, and the conditions for preventing motion interference are given. The accuracy and effectiveness of the proposed methods are verified by numerical simulations, and the complete unfolding and folding process of the deployable protective shield is also demonstrated. The methods proposed in this paper are all general and can be easily generalized to further and more complex situations. Finally, a case is shown where the deployable protective shield can be applied to a spacecraft like the Spitzer Space Telescope.近年来,随着人们对太空的探索越来越频繁,各种航天器被发射到太空中。宇宙中的空间碎片和辐射以及太阳的不规则活动,如太阳耀斑和太阳风暴,都会对航天器产生严重影响。防护罩是保护航天器免受空间碎片、辐射和其他损害的有利措施。在这项研究中,受软体动物行为的启发,首次提出了航天器的防护盾。然后将折纸的概念引入到折叠和展开方案的设计中。保护罩有一定的厚度,虽然厚度不显著,可以认为是薄壁结构,但不能视为零厚度折纸,因为即使很小的厚度也会引起运动干扰等问题。这项研究提出了增厚面板的三条准则。通过空间几何的推导,提出了一种空间曲面增厚的方法。该方法很好地解决了加厚过程中顶点间的兼容性问题,同时又保证了每个面板的可制造性。在此基础上,提出了一种基于空间矢量判断厚板曲面折纸是否发生运动干涉的计算方法,并给出了防止运动干涉的条件。通过数值仿真验证了所提方法的准确性和有效性,并演示了可展开防护罩展开和折叠的完整过程。本文提出的方法都是通用的,可以很容易地推广到更复杂的情况。最后,给出了将可展开防护盾应用于斯皮策太空望远镜等航天器的实例。来源:复合材料力学仿真Composites FEM

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