【新文速递】2024年5月30日固体力学SCI期刊最新文章

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今日更新：Journal of the Mechanics and Physics of Solids 3 篇，International Journal of Plasticity 1 篇，Thin-Walled Structures 2 篇

Journal of the Mechanics and Physics of Solids

A finite geometry, inertia assisted coarsening-to-complexity transition in homogeneous frictional systems

Thibault Roch, Efim A. Brener, Jean-François Molinari, Eran Bouchbinder

doi:10.1016/j.jmps.2024.105706

有限几何，惯性辅助粗糙到复杂的过渡均质摩擦系统

The emergence of statistical complexity in frictional systems (where nonlinearity and dissipation are confined to an interface), manifested in broad distributions of various observables, is not yet understood. We study this problem in velocity-driven, homogeneous (no quenched disorder) unstable frictional systems of height H. The latter are described at the continuum scale within a realistic rate-and-state friction interfacial constitutive framework, where elasto-frictional instabilities emerge from rate-weakening friction. For large H, such frictional systems were recently shown to undergo continuous coarsening until settling into a spatially periodic traveling solution. We show that when the system’s height-to-length ratio becomes small — characteristic of various engineering and geophysical systems —, coarsening is less effective and the periodic solution is dynamically avoided. Instead, and consistently with previous reports, the system settles into a stochastic, statistically stationary state. The latter features slip bursts, whose slip rate is larger than the driving velocity, which are non-trivially distributed. The slip bursts are classified into two types: predominantly non-propagating, accompanied by small total slip and propagating, accompanied by large total slip. The statistical distributions emerge from dynamically self-generated heterogeneity, where both the non-equilibrium history of the interface and wave reflections from finite boundaries, mediated by material inertia, play central roles. Specifically, the dynamics and statistics of large bursts reveal a timescale ∼H/cs, where cs is the shear wave-speed. We discuss the robustness of our findings against variations of the frictional parameters, most notably affecting the magnitude of frictional rate-weakening, as well as against different interfacial state evolution laws. Finally, we demonstrate a reverse transition in which statistical complexity disappears in favor of the spatially periodic traveling solution. Overall, our results elucidate how relatively simple physical ingredients can give rise to the emergence of slip complexity.

在摩擦系统中（非线性和耗散仅限于界面），统计复杂性（表现为各种可观测量的广泛分布）尚未得到理解。我们研究了在速度驱动、均匀（无随机扰动）不稳定摩擦系统中出现的这一问题，该系统高度为H。后者在连续尺度上被描述为一个现实的速率和状态摩擦界面本构框架，其中弹性摩擦不稳定性源于速率减弱摩擦。对于大H，最近的研究表明，此类摩擦系统会经历连续的粗化过程，直到进入一个具有空间周期性移动解的稳定状态。我们证明，当系统的高度与长度之比变得很小（这是各种工程和地球物理系统的特征）时，粗化效果会降低，并且会动态地避免周期性解。相反，与之前的报告一致，系统会进入一个随机的、统计稳定的状态。后者具有滑移脉冲，其滑移速率大于驱动速度，并且非平凡地分布。滑移破裂可以分为两类：以非传播为主的，伴有较小的总滑移量，以及以传播为主的，伴有较大的总滑移量。这些统计分布是由动态自生的异质性产生的，其中界面的非平衡历史和由材料惯性介导的有限边界的波反射在起关键作用。特别是，大的滑移破裂的动力学和统计特性揭示了一个时间尺度约为H/cs，其中cs是剪切波速度。我们讨论了研究结果对摩擦参数变化的鲁棒性，尤其是对摩擦率弱化的幅度的影响，以及对不同界面状态演化规律的影响。最后，我们展示了一个反向转变，其中统计复杂性让位于空间周期性的旅行解。总的来说，我们的研究结果阐明了相对简单的物理成分如何导致滑移复杂性的出现。

Configuration space of helical chiral self-assembly of micro/nano-fibers

Juntao Chen, Langquan Shui, Tao Ding, Ze Liu

doi:10.1016/j.jmps.2024.105708

微/纳米纤维螺旋手性自组装的构型空间

As undertaking various key functions, helical chiral structures are widely presented in nature. Herein, we develop a general theoretical framework to guide the formation of helical chiral structures through self-assembly of micro/nano-fibers driven by adhesion. By analyzing the spiral contact geometric characteristics of multiple fibers and extending the JKR theory, an analytical model for adhesive contact between helical interfaces is proposed. Further, the complete configuration space of self-assembled fibers depending on the adhesion work, elastic modulus, aspect ratio, and initial helix angle is theoretically analyzed. A diversity of helical configurations that far beyond existing experimental findings are predicted, which stems from the existence of multiple energy minimum points on the configuration-energy map. This work reveals the mechanism of adhesion-driven helical chiral structures, and provides theoretical foundation for guiding high-efficient fabrication of helical chiral structures through self-assembly method, which could promote the wide application of chiral structures in fields such as optics, catalysis and drug screening.

螺旋手性结构承担着多种关键功能，在自然界中广泛存在。在此，我们开发了一个通用的理论框架来指导通过由粘附驱动的微/纳米纤维自组装形成螺旋手性结构。通过对多纤维螺旋接触几何特性的分析，在JKR理论的基础上，提出了螺旋界面间粘接接触的解析模型。进一步，从理论上分析了自组装纤维随粘接功、弹性模量、纵横比和初始螺旋角的完整构形空间。由于构型-能量图上存在多个能量极小点，我们预测了远超现有实验结果的螺旋构型的多样性。本研究揭示了黏附驱动螺旋手性结构的机理，为指导利用自组装方法高效制备螺旋手性结构提供了理论基础，可促进手性结构在光学、催化、药物筛选等领域的广泛应用。

Mechanical characterization and constitutive modeling of additively-manufactured polymeric materials and lattice structures

Xiao Guo, Erdong Wang, Hang Yang, Wei Zhai

doi:10.1016/j.jmps.2024.105711

增材制造高分子材料和晶格结构的力学表征和本构建模

Additively manufactured polymeric lattice structures are being extensively studied, primarily because their mechanical properties can be tailored by controlling the unit cell geometry, giving them higher designability than stochastic materials. However, the inherent layer-wise additive manufacturing process affects the base material properties related to the printing direction, which in turn affects the macroscopic responses of the entire lattice materials. A robust understanding and modeling of lattice structures' elastic and plastic yield behavior in a homogenized approach are essential to enhance their design and analysis efficiency in engineering applications. In pursuit of this goal, a unified printing angle-dependent constitutive model of base materials is proposed in line with the tensile experimental data. The elastic material properties (elastic modulus, shear modulus, and Poisson's ratio), obtained through numerical simulations of one unit-cell with periodic boundary conditions, exhibit anisotropic properties, with the degree of anisotropy determined by the angle of the constituent members and base materials. Furthermore, both experimental and numerical results of lattices demonstrate anisotropic mechanical response under horizontal and vertical compression. Virtual multiaxial experiments are conducted through multi-cell numerical simulations, enabling the determination of initial yielding points of two different lattice structures (Kelvin and Simple cubic and body-centered cubic hybrid structures) under various loading conditions using a dissipation energy-based criterion. Overall, the multiaxial yield surface of the investigated lattices under various stress states, except for the isotropic principal stress plane, can be properly depicted by the Extended-Hill anisotropic yield criterion.

增材制造的聚合物晶格结构正在被广泛研究，主要是因为它们的机械性能可以通过控制单元胞的几何形状来定制，这使得它们比随机材料具有更高的可设计性。然而，固有的分层增材制造工艺会影响与打印方向相关的基材性能，进而影响整个晶格材料的宏观响应。在均匀化方法中对晶格结构的弹性和塑性屈服行为的稳健理解和建模对于提高其在工程应用中的设计和分析效率至关重要。为实现这一目标，结合拉伸实验数据，提出了统一的基材打印角度相关本构模型。通过周期性边界条件下的单胞数值模拟得到的弹性材料性能(弹性模量、剪切模量和泊松比)表现出各向异性，各向异性的程度由组成构件和基材的夹角决定。此外，实验结果和数值结果都表明，在水平和垂直压缩下，晶格的力学响应是各向异性的。通过多单元数值模拟进行了虚拟多轴实验，利用基于耗散能的准则确定了不同载荷条件下两种不同晶格结构(开尔文和简单立方以及体心立方混合结构)的初始屈服点。总体而言，除各向同性主应力面外，不同应力状态下晶格的多轴屈服面均可以用扩展-希尔各向异性屈服准则来描述。

International Journal of Plasticity

Tri-functional co-nanoprecipitates enhanced cryogenic ductility by inducing structural heterogeneity and refining nano-twins in a low-stacking-fault-energy 17Mn steel

Xiaoli Chu, Yu Li, Chun Xu, Wei Li, Bin Fu, Xiaoshuai Jia

doi:10.1016/j.ijplas.2024.104014

三官能团共纳米沉淀物通过诱导组织非均质性和细化纳米孪晶来增强低叠错能17Mn钢的低温延展性

In this study, an innovative tri-functional co-nanoprecipitation strategy was employed to enhance the mechanical properties of a low stacking-fault energy (SFE) 17Mn steel for cryogenic applications. By combining severe cold deformation and subsequent annealing, a hierarchical structure emerged, featuring (Ti, Nb)C carbide (∼10 nm) and Cu-rich intermetallic (∼2 nm) in the austenitic matrix with heterogeneous grain size distributions. The co-precipitation (CP) sample exhibited superior performance compared to single-precipitation (SP) steel, with a yield strength of ∼1150 MPa, tensile elongation of ∼44.8%, and an impact toughness of ∼110 J at liquid nitrogen temperature (LNT), even surpassing the base-17Mn steel. The CP-17Mn samples displayed a higher density and thinner nano-twins at larger strains, leading to a rapid increase in geometrically necessary dislocations (GNDs). The detrimental martensitic transformation was effectively suppressed during both tensile and impact tests. The observed inverse strength-ductility and strength-toughness trade-off can be attributed to the tri-functional co-precipitates’ roles: they provide disperse strengthening, induce structural heterogeneity, and act as effective barriers for twin thickening. The large-sized (Ti, Nb)C carbides facilitate grain refinement and pin boundary migration, while the smaller Cu-rich intermetallic inhibits the growth and thickening of nano-twins, preventing further dislocation movement due to their strong stress fields at the twin-precipitate interactions. This novel mechanism paves the way for developing higher-performance steels with fine and dense nano-twins at cryogenic conditions.

在这项研究中，采用一种创新的三功能共纳米沉淀策略来提高低温应用中低堆叠-故障能(SFE) 17Mn钢的力学性能。通过结合严重的冷变形和随后的退火，形成了一个层次结构，在奥氏体基体中具有(Ti, Nb)C碳化物(~ 10 nm)和富cu金属间化合物(~ 2 nm)，晶粒尺寸分布不均匀。与单析出(SP)钢相比，共析出(CP)样品表现出更好的性能，屈服强度为~ 1150 MPa，拉伸伸长率为~ 44.8%，在液氮温度(LNT)下的冲击韧性为~ 110 J，甚至超过了基17mn钢。在较大的应变下，CP-17Mn样品显示出更高的密度和更薄的纳米孪晶，导致几何必要位错(GNDs)迅速增加。在拉伸和冲击试验中，有害的马氏体相变得到有效抑制。所观察到的强度-延展性和强度-韧性的反向权衡可归因于三功能共析出物的作用:它们提供分散强化，诱导结构非均质性，并作为孪生增厚的有效屏障。大尺寸的(Ti, Nb)C碳化物促进晶粒细化和针脚边界迁移，而较小的富cu金属间化合物抑制纳米孪晶的生长和增厚，由于孪晶与析出相相互作用时的强应力场，阻止了进一步的位错运动。这一新的机制为在低温条件下开发具有精细和致密纳米孪晶的高性能钢铺平了道路。

Thin-Walled Structures

Exact three-dimensional elasticity analysis for buckling of composite laminated plates resting on viscoelastic foundation

Meisam Kheradpisheh, Mehdi Hojjati

doi:10.1016/j.tws.2024.112060

粘弹性基础上复合材料层合板屈曲的精确三维弹性分析

This paper aims to present novel exact solutions for the buckling of a laminated plate resting on the viscoelastic foundation with both normal and shear viscoelastic layers. The governing equations of plate buckling are derived using three-dimensional elasticity theory and state-space formulation. The normal and shear layers of the viscoelastic foundations are modeled using the generalized Maxwell model to represent both the elastic and viscose properties of the foundation. To couple the viscoelastic foundation equation with the buckling equation, Boltzmann’s superposition principle along with the Laplace transform is utilized. Then, the effects of geometry, relaxation modulus of normal and shear layers, viscosity, and time are investigated on the buckling load. The results reveal that the higher viscosity coefficient leads to a slower rate of change in the buckling loads. In addition, the viscoelastic properties have a significant impact on the buckling behavior of the plate. In this regard, the results show that instead of the expected second mode at a constant aspect ratio, the plate experiences the first mode as time passes. The computed results also show that there is a critical threshold. When the foundation stiffness exceeds this threshold, the conventional method of reducing the aspect ratio to prevent buckling not only proves ineffective in reducing the probability of buckling but also, in fact, leads to an increase in buckling occurrences. In addition to the analytical investigation, a finite element (FE) analysis is carried out to study the buckling response of the composite plate. The finite element results also show a reasonably good agreement with those of the analytical method.

本文旨在提出具有正弹性层和剪切粘弹性层的粘弹性基础上叠合板屈曲的新颖精确解。利用三维弹性理论和状态空间公式推导了板屈曲的控制方程。采用广义Maxwell模型对粘弹性地基的法向层和剪切层进行了建模，以反映地基的弹性和粘性。利用玻尔兹曼叠加原理和拉普拉斯变换将粘弹性基础方程与屈曲方程耦合起来。然后，研究了几何形状、法向层和剪切层松弛模量、黏度和时间对屈曲载荷的影响。结果表明，黏度系数越高，屈曲载荷的变化率越慢。此外，粘弹性特性对板的屈曲行为有显著影响。在这方面，结果表明，随着时间的推移，板经历的不是预期的第二模态，而是第一模态。计算结果也表明存在一个临界阈值。当基础刚度超过该阈值时，传统的减小长径比防止屈曲的方法不仅不能有效降低屈曲的概率，反而会导致屈曲发生的增加。在分析研究的基础上，对复合材料板的屈曲响应进行了有限元分析。有限元计算结果与解析计算结果也有较好的一致性。

Eccentric compression behavior of L-shaped column fabricated by thin-walled square steel tubes based on self-drilling screw connections

Xiaodun Wang, Jincheng Jiang, Yang Liu, Zhihua Chen

doi:10.1016/j.tws.2024.112063

基于自钻螺纹连接的薄壁方钢管l形柱偏心受压特性

In this study, a new L-shaped column fabricated by thin-walled square steel tubes (LFTST columns) based on self-drilling screw connections is proposed. The LFTST columns consisted of square steel tubes, U-shaped parts, angle parts, gusset plates, and self-drilling screw connections. LFTST columns possess several advantages including easy transportation, rapid assembly, and eco-friendliness. Consequently, they are suitable for low-rise buildings, such as village-building, low-rise dormitories, and low-rise office buildings. However, the compression behavior of LFTST columns remains silent. Five full-scale LFTST column specimens were subjected to eccentric compression tests. The variables under consideration included eccentricity (with values of 0mm, 40mm, and 80mm), thickness (2mm and 4mm), and the number of gusset plates (0, 1, and 3). The failure modes, bearing capacity, load-displacement response, and strain development of the LFTST specimens were obtained. Subsequently, finite element (FE) models of LFTST columns were established and used to analyze the eccentric compression behavior of LFTST columns. The FE modeling results agreed well with the experimental results. A detailed parameter analysis was conducted to evaluate the effects of various factors. These factors included the thickness of the plates (2mm, 3mm, and 4mm), the width of the gusset plates (100mm, 150mm, and 200mm), limb spacing values (0mm, 150mm, and 300mm), and eccentricity (0mm, 20mm, 40mm, 60mm, and 80mm). In addition, the calculation formula for estimating the ultimate bearing capacity of the LFTST columns was derived employing the double coefficient product method. The proposed formula was validated by experimental and FE results.

本文提出了一种基于自钻螺纹连接的薄壁方钢管l形柱(LFTST柱)。LFTST柱由方钢管、u型件、角件、扣板和自钻螺钉连接组成。LFTST柱具有运输方便、组装快速、环保等优点。因此，适用于低层建筑，如村舍、低层宿舍、低层写字楼等。然而，LFTST列的压缩行为保持沉默。对5个全尺寸LFTST柱试件进行了偏心压缩试验。考虑的变量包括偏心(0 mm、40mm和80mm)、厚度(2mm和4mm)和扣板数量(0、1和3)。得到了LFTST试件的破坏模式、承载能力、荷载-位移响应和应变发展。随后，建立了LFTST柱的有限元模型，并对LFTST柱的偏心受压行为进行了分析。有限元模拟结果与试验结果吻合较好。对各因素的影响进行了详细的参数分析。这些因素包括板的厚度(2mm, 3mm和4mm)，扣板的宽度(100mm, 150mm和200mm)，肢间距值(0mm, 150mm和300mm)和偏心率(0mm, 20mm, 40mm, 60mm和80mm)。此外，采用双系数乘积法推导了LFTST柱极限承载力的计算公式。实验和有限元结果验证了所提公式的正确性。

来源：复合材料力学仿真Composites FEM

【新文速递】2024年5月13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 1 篇，Composites Part B: Engineering 1 篇，Composites Science and Technology 1 篇Composite StructuresVariable angle tow-steered curvilinear fibres-based rotating arbitrarily layered composite beams- a coupled vibration of chordwise-flapwise-torsional motions by higher-order beam theoryLingesh Balaji, Ganapathi Manickam, Olivier Polit, Mohamed Haboussi, Sachin Dineshkumardoi:10.1016/j.compstruct.2024.118199基于变角拖曳曲线纤维的旋转任意层状复合梁-高阶梁理论的弦向-旋向-扭向耦合振动In the present work, variable angle tow-steered curvilinear fibres-based straight composite rotating beam is studied for its coupled vibrational behaviours from different beam planes by a higher-order beam formulation satisfying plane stress situation and combining with finite element methodology. The structural theory is extended to include all the vibrational motions including chord- and flap-wise motions, axial and torsional vibrations of beam. The centrifugal force stiffening and gyroscopic effects stemming from rotational motions are taken into the formulation. The generic differential equations of equilibrium for the proposed structural theory are evolved adopting virtual dynamic work, Hamilton’s principle and a suitable C1 continuity based elemental equations are gotten. The newly constructed finite element formulation is tested for solved problems that are known in the literature. Based on in-depth analysis, vibration features of curvilinear fibre-based rotating generally layered composite beam including coupled dynamic motions in terms of vibrational modes and their frequencies pertaining to chord- and flap-wise, axial, torsional motions are detailed presuming variable angles along the curvilinear fibre path at the centre and layer edge, short and long beams, hub-radius, beam cross-section, and high rotational speed effects.本文采用满足平面应力情况的高阶梁公式，结合有限元方法，研究了变角拖向曲线纤维直复合旋转梁在不同梁平面上的耦合振动特性。将结构理论扩展到包括梁的弦振和扑翼振、轴振和扭振在内的所有振动运动。公式中考虑了由旋转运动引起的离心力加强和陀螺效应。采用虚动力功、Hamilton原理和合适的C1连续性元素方程，推导了该结构理论的一般平衡微分方程。新构建的有限元公式对已知文献中已解决的问题进行了测试。在深入分析的基础上，详细分析了基于曲线纤维的旋转层状复合梁的振动特征，包括沿曲线纤维路径中心和层边缘、短梁和长梁、轴向、轴向、扭转等角度的振动模式和频率耦合动力运动，以及高转速效应。Temperature-dependent debonding behavior of adhesively bonded CFRP-UHPC interfaceWei Zhang, Jinwei Lin, Yiqun Huang, Benqing Lin, Shuaiwen Kangdoi:10.1016/j.compstruct.2024.118200CFRP-UHPC界面温度相关脱粘行为研究The adhesively bonded structure, comprising carbon fiber-reinforced polymer (CFRP) and ultra-high-performance concrete (UHPC), enhances structural strength while reducing brittleness and strain softening behavior. However, the adhesively bonded structure is inevitably influenced by temperature variations throughout its service life. When the adhesive layer's temperature surpasses the glass transition temperature (Tg), significant damage occurs to the bond layer joint. To investigate the debonding behavior of the CFRP-UHPC interface at various temperatures, a series of three-point-bending tests were conducted at room temperature, 120%Tg, 150%Tg, and 160%Tg. This study introduced a temperature degradation factor, employing a proposed maximum load capacity prediction formula to adjust both the test results and data from other researchers. By adjusting the cohesion parameters with the temperature degradation factor, a temperature-dependent mixed-mode cohesive zone model (CZM) was developed. The model's validity was confirmed through finite element (FE) analysis, considering two distinct experimental scenarios. The paper concludes that the proposed model effectively simulates interface debonding behavior across varying temperatures.由碳纤维增强聚合物（CFRP）和超高性能混凝土（UHPC）组成的粘接结构可增强结构强度，同时降低脆性和应变软化行为。然而，粘接结构在整个使用寿命期间不可避免地会受到温度变化的影响。当粘合层的温度超过玻璃化转变温度（Tg）时，粘合层接缝就会发生严重破坏。为了研究 CFRP-UHPC 界面在不同温度下的脱粘行为，分别在室温、120%Tg、150%Tg 和 160%Tg 下进行了一系列三点弯曲试验。这项研究引入了温度退化因子，并采用了建议的最大承载能力预测公式来调整试验结果和其他研究人员的数据。通过用温度退化因子调整内聚力参数，建立了与温度相关的混合模式内聚带模型（CZM）。考虑到两种不同的实验情况，通过有限元（FE）分析证实了该模型的有效性。本文的结论是，所提出的模型能有效模拟不同温度下的界面脱粘行为。In-Plane crushing performance of bionic glass Sponge-Type honeycomb structuresYuyang Wang, Guoxing Lu, Ngoc San Ha, Li Wangdoi:10.1016/j.compstruct.2024.118201仿生玻璃海绵型蜂窝结构的面内破碎性能Honeycomb structures are commonly adopted due to their superior energy absorption capacity. In this study, a new bionic glass sponge–type honeycomb structure (BSH) with a quadrilateral octagonal mesh microstructure inspired by the sea sponge structure was proposed. The in-plane crushing performance of the BSH with different geometrical parameters under different crushing speeds was investigated by ABAQUS/Explicit. The numerical findings suggested that the BSH displayed stronger energy absorption in contrast to the square, hexagonal and hierarchical honeycombs at both quasi-static and dynamic crushing conditions. More plastic hinges and more unit walls involved in deformation resulted in a high energy absorption capacity. In addition, three typical deformation modes of the BSH under different loading speeds were discussed, and the empirical model to predict the plateau stress of the BSH was established based on the shock wave theory. Finally, the effect of boundary segmentation parameter m on crushing performance was also illustrated. The energy absorption capacity reaches a maximum at m = 3 for quasi–static loading, whereas at m = 5 for dynamic loading. These findings provide valuable insights into the optimization of bionic honeycombs.蜂窝状结构由于具有较好的吸能能力而被普遍采用。在本研究中，受海绵结构的启发，提出了一种具有四边形八边形网状结构的仿生玻璃海绵型蜂窝结构(BSH)。采用ABAQUS/Explicit软件，对不同几何参数的BSH在不同破碎速度下的面内破碎性能进行了研究。数值结果表明，在准静态和动态破碎条件下，BSH比正方形、六边形和分层蜂窝具有更强的能量吸收。更多的塑性铰链和更多的单元壁参与变形导致了高的能量吸收能力。此外，讨论了不同加载速度下BSH的三种典型变形模式，建立了基于激波理论的BSH平台应力预测经验模型。最后，分析了边界分割参数m对破碎性能的影响。准静态加载时，吸能能力在m = 3处达到最大值，动加载时，吸能能力在m = 5处达到最大值。这些发现为仿生蜂窝的优化提供了有价值的见解。Nanocomposite fracture analysis: Aligned Fe3O4-GNP nanoplatelets’ effects on KIC, GIC, CTODc, and fracture mechanisms in epoxy matricesAnupam Tiwaridoi:10.1016/j.compstruct.2024.118208纳米复合材料断裂分析：排列整齐的 Fe3O4-GNP 纳米颗粒对环氧树脂基质中 KIC、GIC、CTODc 和断裂机制的影响Epoxy nanocomposites are crucial in aerospace, enhancing structural performance, reducing weight, and improving fuel efficiency across various applications. They ensure safety, reliability, and optimal performance in critical aerospace systems. Optimizing fracture properties like crack growth resistance (KIC), critical stress intensity factor (GIC), and critical crack tip opening displacement (CTODc), is vital for safety, durability, and innovation, especially in epoxy nanocomposites under extreme conditions. This study examines how random Graphene Nanoplatelets (GNP) and aligned Fe3O4-GNP nanoplatelets impact the fracture resistance of epoxy nanocomposites. It analyzes various fracture properties and crack propagation mechanisms following ASTM D5045-99 standards for CT specimen toughness tests using a COD gauge, focusing on nanoparticle alignment and wt% loading effects. Neat epoxy has a KIC of 0.94 MPa m1/2, increasing to 1.20 with 0.600 wt% GNP. Aligned Fe3O4-GNP peaks at 1.49. the baseline GIC starts at 209 J/m2 and rises to 301 J/m2 with 0.600 wt% GNP, and notably to 419J/m2 with aligned Fe3O4-GNP. Aligned Fe3O4-GNP significantly enhances fracture properties by modifying stress distribution at primary crack fronts through mechanisms such as deflection, branching, and twisting. These findings offer crucial insights for improving epoxy nanocomposites in aerospace, ensuring increased safety, reliability, and performance in critical components.环氧纳米复合材料在航空航天领域至关重要，它能在各种应用中增强结构性能、减轻重量并提高燃料效率。它们可确保关键航空航天系统的安全性、可靠性和最佳性能。优化裂纹生长阻力（KIC）、临界应力强度因子（GIC）和临界裂纹尖端张开位移（CTODc）等断裂性能对于安全性、耐用性和创新性至关重要，尤其是在极端条件下的环氧纳米复合材料。本研究探讨了随机石墨烯纳米片（GNP）和排列的 Fe3O4-GNP 纳米片如何影响环氧纳米复合材料的抗断裂性。该研究按照 ASTM D5045-99 标准，使用 COD 仪进行 CT 试样韧性测试，分析了各种断裂特性和裂纹扩展机制，重点关注纳米颗粒排列和 wt% 负载的影响。纯环氧树脂的 KIC 值为 0.94 MPa m1/2，当 GNP 含量为 0.600 wt%时，KIC 值增至 1.20。对齐的 Fe3O4-GNP 的峰值为 1.49。基线 GIC 从 209 J/m2 开始，在 GNP 含量为 0.600 wt% 时上升到 301 J/m2，而在对齐的 Fe3O4-GNP 中则明显上升到 419 J/m2。对齐的 Fe3O4-GNP 通过偏转、分支和扭曲等机制改变了原生裂纹前沿的应力分布，从而显著提高了断裂性能。这些发现为改进航空航天领域的环氧纳米复合材料，确保提高关键部件的安全性、可靠性和性能提供了重要启示。Exploring in-plane shear characteristics of multilayer biaxial weft knitted fabrics through a micro-scale virtual fiber modelingLiwei Wu, Kanghui Zhou, Feng Zhao, Shengkai Liu, Junbo Xie, Liangsen Liu, Peng Cao, Youhong Tang, Qian Jiangdoi:10.1016/j.compstruct.2024.118209通过微尺度虚拟纤维建模，探索多层双轴纬针织物的面内剪切特性The multilayer biaxial weft knitted (MBWK) fabrics and their composites have been widely applied in fields of complex structural products due to their flexible curved deformability. The existence of stitch in MBWK complicates the deformation behavior under the in-plane shear loading. However, it has not been well explored and understood. In this study, a numerical micro-scale virtual fiber modeling was built to investigate the in-plane shear performance of MBWK by considering the micro geometric features and fiber property that are difficult to be characterized solely by experiment. The strain conditions of the stitch that determine the fabric shear behavior are discussed. The deformation behavior leads to local deformation and morphological locking of the stitch. In the early stage of the shearing, the deformability of stitch provides enough space to accommodate the rearrangement of axial yarns. In the shear locking stage, the restriction of stitch and compression within axial yarns at high shear angles restricts the axial yarns from movement in the loading direction. When the theoretical shear angle is 20°, the shear angle located in different shear regions varies. The maximum shear angle near the loading area is 19.1°, while the minimum shear angle near the fixed area is approximately 17°. The results illustrate the deformation mechanism of MBWK under in-plane shearing and provide an excellent guidance for the design of large deformation fabrics, especially for curved surfaces, thus realize the effective utilization of fabrics in engineering applications.多层双轴纬编织物及其复合材料由于具有柔性弯曲变形能力，在复杂结构产品领域得到了广泛的应用。缝的存在使MBWK在面内剪切荷载作用下的变形行为复杂化。然而，它还没有被很好地探索和理解。为了研究MBWK的面内剪切性能，考虑到MBWK的微观几何特征和纤维性能难以通过实验表征的特点，建立了数值微尺度虚拟纤维模型。讨论了决定织物剪切性能的针脚应变条件。这种变形行为导致针脚局部变形和形态锁紧。在剪切初期，针段的变形性为轴向纱线的重新排列提供了足够的空间。在剪切锁紧阶段，大剪切角时轴向纱内的针距和压缩受到限制，限制了轴向纱在加载方向上的运动。当理论剪切角为20°时，位于不同剪切区的剪切角是不同的。加载区附近最大剪切角为19.1°，固定区附近最小剪切角约为17°。研究结果阐明了MBWK在面内剪切作用下的变形机理，为大变形织物特别是曲面织物的设计提供了良好的指导，从而实现了织物在工程应用中的有效利用。Composites Part A: Applied Science and ManufacturingThe moisture absorption of 3D printed short carbon fibre reinforced polyamideY. Houdoi:10.1016/j.compositesa.2024.1082663D打印短碳纤维增强聚酰胺的吸湿性能Polymer composites are commonly exposed to humid conditions and undergo reductions in mechanical properties. It is challenging to describe the moisture absorption dynamics of 3D printed parts due to manufacture-induced microstructures. This work investigates the moisture absorption of 3D printed short carbon fibre reinforced polyamide with varied microstructures and resulting influence on mechanical properties. The printed composites have inferior microstructures compared to the polyamide and diffusivity increases with the number of interlayer interfaces by up to 119 % (three times that of compression moulded composite). The microstructure is permanently aggravated by moisture resulting in more significant and irreversible reductions in yield stress (39 to 59 %) and tensile modulus (65 to 79 %) compared to injection moulded samples. Additionally, the shear modulus of printed polyamide and composites decrease by up to 63 % and 74 %, respectively. The results are helpful for prediction, evaluation, and maintenance of 3D printed applications subject to moisture environment.聚合物复合材料通常暴露在潮湿条件下，机械性能会降低。由于制造诱导的微结构，描述3D打印部件的吸湿动力学具有挑战性。本研究研究了3D打印不同微观结构的短碳纤维增强聚酰胺的吸湿性及其对力学性能的影响。与聚酰胺相比，打印的复合材料具有较差的微观结构，扩散率随着层间界面数量的增加而增加高达119% %(是压缩成型复合材料的三倍)。与注射成型样品相比，受潮会导致微观结构永久性恶化，从而导致屈服应力(39%至59% %)和拉伸模量(65%至79% %)更显著且不可逆的降低。此外，打印聚酰胺和复合材料的剪切模量分别降低了63 %和74 %。研究结果有助于潮湿环境下3D打印应用的预测、评估和维护。Composites Part B: EngineeringHighly sensitive and selective flexible anisotropic strain sensor based on liquid metal/conductive ink for wearable applicationsChao Ma, Kai Wang, Dayong Gao, Gang Zhaodoi:10.1016/j.compositesb.2024.111538 基于可穿戴应用的液态金属/导电油墨的高灵敏度和选择性柔性各向异性应变传感器Although many high-performance wearable strain sensors have been developed, they are limited to uniaxial strain monitoring, which makes it challenging to meet the monitoring needs of complex multidimensional motion in practical applications. This study effectively constructed an anisotropic strain sensor by combining two materials that exhibit different responses to external stimuli (strain): liquid metal and conductive ink. In particular, the maximum gauge factors of this anisotropic strain sensor in conductive ink direction and liquid metal direction are 158.9 and 1.9, respectively. Both directions display outstanding dynamic stability, frequency independence, and durability over 3000 cycles. Furthermore, the integrated sensor formed by the orthogonal stack of two anisotropic strain sensors can distinguish the strain magnitude and direction (an outstanding selectivity of 3.7). The mechanism of the sensor's selective sensing ability is analyzed, and the broad application of the sensor in complex motion monitoring, human-computer interaction, and multi-component control is demonstrated. This research discovery provides new ideas and methods for constructing anisotropic wearable strain sensors. It creates conditions for the development and practical application of multifunctional wearable devices.虽然目前已经开发出许多高性能的可穿戴应变传感器，但它们都局限于单轴应变监测，难以满足实际应用中复杂多维运动的监测需求。本研究通过结合液态金属和导电油墨这两种对外部刺激(应变)表现出不同反应的材料，有效地构建了一种各向异性应变传感器。特别是，该各向异性应变传感器在导电油墨方向和液态金属方向的最大测量系数分别为158.9和1.9。两个方向都显示出出色的动态稳定性，频率无关性和超过3000次循环的耐久性。此外，由两个各向异性应变传感器正交堆叠而成的集成传感器可以区分应变的大小和方向(选择性为3.7)。分析了传感器选择性感知能力的机理，论证了传感器在复杂运动监测、人机交互、多组分控制等方面的广泛应用。这一研究发现为构建各向异性可穿戴应变传感器提供了新的思路和方法。为多功能可穿戴设备的发展和实际应用创造了条件。Composites Science and TechnologyA physics-guided deep learning model for predicting the magneto-induced mechanical properties of magnetorheological elastomer: small experimental data-drivenHang Ren, Dan Zhao, Liqiang Dong, Shaogang Liu, Jinshui Yangdoi:10.1016/j.compscitech.2024.110653 用于预测磁流变弹性体磁致力学性能的物理指导深度学习模型:小型实验数据驱动Magnetorheological elastomer (MRE) is a novel intelligent material, which shows excellent potential in vibration control applications. Previous researches have fully demonstrated that the magneto-induced shear storage modulus of MRE largely determines the vibration control effect. However, both existing theoretical and experimental ways to measure the magneto-induced shear storage modulus of MRE face their own shortage. Therefore, a novel physics-guided deep learning model is proposed to efficient predict the magneto-induced mechanical properties of MRE based on Magnetic Dipole theory and data-driven methods. A small database is built by collecting the magneto-induced shear storage modulus of MRE with different material ratios tested on a special shear rheometer. The proposed model trained with small training samples and its prediction results fit well with experimental values (average R2 of 0.99) which is superior to existing constitutive models. The training only takes 25 seconds, which significantly shortens the time compared to the experiment. Furthermore, the proposed model effectively predicts the magneto-induced storage modulus of MRE and has good generalization and superior transfer performance.磁流变弹性体(MRE)是一种新型的智能材料，在振动控制方面具有良好的应用潜力。以往的研究充分表明，磁致剪切存储模量在很大程度上决定了磁致剪切存储模量的减振效果。然而，现有的磁致剪切存储模量的理论和实验测量方法都存在各自的不足。为此，提出了一种基于磁偶极子理论和数据驱动方法的物理引导深度学习模型，以有效预测磁致机械性能。通过在专用剪切流变仪上采集不同材料配比的磁致剪切存储模量，建立了一个小型数据库。该模型采用小样本训练，预测结果与实验值拟合良好(平均R2为0.99)，优于现有的本构模型。训练只需要25秒，与实验相比，这大大缩短了时间。此外，该模型能有效地预测MRE的磁致存储模量，具有良好的泛化性和优异的传输性能。来源：复合材料力学仿真Composites FEM