【新文速递】2023年10月3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 Science and Technology 2 篇

Composite Structures

3D viscoelastic solutions for bending creep of layered rectangular plates under time-varying load

Li Xiaolong, Wu Peng, Fang Hai, Wang Jie, Yu Yunwei

doi:10.1016/j.compstruct.2023.117590

层状矩形板在时变载荷作用下弯曲蠕变的三维粘弹性解法

Creep behavior is an inevitable problem for viscoelastic layered structures and needs to be predicted for long-term service situations. In this study, a new technique to obtain analytical solutions for three-dimensional (3D) viscoelastic equations for layered rectangular plates under time-varying loads is developed to predict bending creep behavior. In the analytical model, all the constituent materials of the plate, including the laminar layers and interlayers, exhibit viscoelastic properties, which are simulated by the Burgers model. The slip effect between neighboring laminar layers due to a relatively soft interlayer is considered. The stresses and displacements of each laminar layer in the layered plates are described by 3D elasticity theory combined with the Boltzmann superposition principle. The viscoelastic analytical solutions are obtained by means of series expansions and the Laplace transformation method. The present solution has good accuracy and agrees with the finite element (FE) solution. The influence of various parameters, such as the modulus degradation pattern, modulus ratio and viscoelastic constants, on the creep of the plate are studied.

蠕变行为是粘弹性层状结构不可避免的问题，需要针对长期使用情况进行预测。在本研究中，开发了一种新技术来获得矩形分层板在时变载荷作用下的三维（3D）粘弹性方程的解析解，从而预测弯曲蠕变行为。在分析模型中，板的所有组成材料，包括层状层和夹层，都表现出粘弹性能，这些粘弹性能由 Burgers 模型模拟。由于夹层相对较软，相邻层板之间的滑移效应也被考虑在内。层状板中各层状层的应力和位移由三维弹性理论结合玻尔兹曼叠加原理描述。粘弹性解析解是通过序列展开和拉普拉斯变换法得到的。本求解具有良好的准确性，并与有限元（FE）求解一致。研究了各种参数（如模量退化模式、模量比和粘弹性常数）对板材蠕变的影响。

Composites Science and Technology

Polyacrylonitrile nanofiber reinforced polyimide composite aerogels with fiber-pore interpenetrating structures for sound absorption, air filtration and thermal insulation

Zhao Xingyu, Ruan Kunpeng, Qiu Hua, Zhang Yali, Gu Junwei

doi:10.1016/j.compscitech.2023.110275

具有纤维孔穿插结构的聚丙烯腈纳米纤维增强聚酰亚胺复合气凝胶，用于吸音、空气过滤和隔热

Prolonged noise pollution and its induced vibration would not only lead to the failure of instruments and equipment, but also endanger human health. In this work, with water-soluble polyamide acid (PAA) as the matrix and polyacrylonitrile nanofiber (PANNF) as the reinforcement, PANNF reinforced polyimide (PANNF/PI) composite aerogels with fiber-pore interpenetrating structures are fabricated by the method of “homogeneous mixing, freeze-drying and heat treatment”. PANNF that intersperses among pores can effectively inhibit the shrinkage of PI aerogels and enhance sound absorption and mechanical properties. With PANNF dosage of 10 wt%, the composite aerogels own the excellent sound absorption performance, with noise reduction coefficient (NRC) of 0.398, and average sound absorption coefficient (SAC) of 0.913 in the frequency range of 2000∼6300 Hz. The composite aerogels also have excellent mechanical properties, with Young's modulus of 12.42 kPa, stress loss of 3.64% and energy loss coefficient of 0.203. 10 wt% PANNF/PI composite aerogels also possess satisfying air filtration performance (97.2% filtration efficiency for PM2.5, quality factor (QF) value of 0.0396 Pa-1; and 99.4% filtration efficiency for PM10, QF value of 0.0567 Pa-1) and thermal insulation performance (thermal conductivity coefficient as low as 0.036 W/(m·K)).

长时间的噪声污染及其引起的振动不仅会导致仪器和设备故障，还会危害人体健康。本研究以水溶性聚酰胺酸（PAA）为基体，聚丙烯腈纳米纤维（PANNF）为增强体，采用 "均匀混合、冷冻干燥、热处理 "的方法制备了具有纤维孔穿插结构的 PANNF 增强聚酰亚胺（PANNF/PI）复合气凝胶。穿插在孔隙中的 PANNF 能有效抑制 PI 气凝胶的收缩，提高吸声性能和机械性能。当 PANNF 的用量为 10 wt%时，复合气凝胶具有优异的吸声性能，降噪系数（NRC）为 0.398，在 2000∼6300 Hz 频率范围内的平均吸声系数（SAC）为 0.913。复合气凝胶还具有优异的机械性能，其杨氏模量为 12.42 kPa，应力损失为 3.64%，能量损失系数为 0.203。10 wt% PANNF/PI 复合气凝胶还具有令人满意的空气过滤性能（对 PM2.5 的过滤效率为 97.2%，质量因子 (QF) 值为 0.0396 Pa-1；对 PM10 的过滤效率为 99.4%，质量因子 (QF) 值为 0.0567 Pa-1）和隔热性能（导热系数低至 0.036 W/(m-K)）。

Constructing interfacial barrier from tribo-positive shell microcapsules to suppress space charge in thermochromic phase change composites for smart electronics

Gao Jian, Wu Kangning, Xie Zongliang, Li Jianying, Li Shengtao

doi:10.1016/j.compscitech.2023.110291

利用三正壳微胶囊构建界面屏障，抑制用于智能电子产品的热致变色相变复合材料中的空间电荷

Thermochromic phase change composites (TPC) exhibit versatile functions under electrothermal stimuli, which are extensively applied as packaging, insulation and circuit components in considerable advanced smart electronics. However, space charge accumulation under DC voltages is still a critical and universal issue for the serious deterioration of functionalities and life-span of TPC and electronics. This study presents a novel strategy of suppressing space charge in thermochromic phase change epoxy composites (TPCE) by constructing interfacial barrier from tribo-positive shell thermochromic phase change microcapsules. The strong tribo-positive melamine-formaldehyde (MF) shell of microcapsules can establish negative charge barriers in the interfaces between microcapsules and epoxy matrix through triboelectrification, which is directly verified by Kelvin probe force microscopy. Pulsed electroacoustic measurement results exhibit the space charge accumulation in TPCE under an extreme electric field strength of 50 kV/mm and an elevated temperature 70 °C can be significantly diminished by 39.3% compared to that of neat epoxy resin after incorporating merely 1 ph MF shell microcapsules, affirming the effect of interfacial barrier on space charge inhibition. The interfacial barrier could improve the charge carrier dissipation and mitigating the space charge accumulation as confirmed by hopping conduction analysis. Moreover, DC breakdown strength of TPCE can also be enhanced by 12.3% and 6.1% with 1phr microcapsules at 30 °C and 70 °C compared to that of neat epoxy resin owing to the suppressed space charge. The results provide a potential approach of designing high-performance thermochromic phase change composites for smart electrical and electronic devices.

热致变色相变复合材料（TPC）在电热刺激下具有多种功能，被广泛应用于各种先进智能电子产品的封装、绝缘和电路元件。然而，直流电压下的空间电荷积累仍然是一个严重的普遍问题，会导致热致变色相变复合材料和电子器件的功能和寿命严重衰减。本研究提出了一种抑制热致变色相变环氧树脂复合材料（TPCE）中空间电荷的新策略，即利用三正壳热致变色相变微胶囊构建界面屏障。微胶囊的三聚氰胺-甲醛（MF）强正壳可通过三电化作用在微胶囊与环氧基体之间的界面上建立负电荷屏障，开尔文探针力显微镜直接验证了这一点。脉冲电声测量结果表明，在 50 kV/mm 的极端电场强度和 70 ℃ 的高温条件下，与纯环氧树脂相比，仅加入 1 ph MF 微胶囊后，TPCE 中的空间电荷积累就能显著减少 39.3%，这肯定了界面屏障对空间电荷抑制的作用。跳变传导分析证实，界面阻挡层可改善电荷载流子耗散，缓解空间电荷积累。此外，由于空间电荷受到抑制，与纯环氧树脂相比，在 30 °C 和 70 °C 温度下，含有 1phr 微胶囊的 TPCE 直流击穿强度分别提高了 12.3% 和 6.1%。这些结果为设计用于智能电气和电子设备的高性能热致变色相变复合材料提供了一种潜在的方法。

来源：复合材料力学仿真Composites FEM

【新文速递】2023年10月6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 1 篇，Mechanics of Materials 1 篇，International Journal of Plasticity 1 篇，Thin-Walled Structures 1 篇International Journal of Solids and StructuresOn the generalized plane strain assumption for pressurized membranesThbaut M., Brisard S.doi:10.1016/j.ijsolstr.2023.112506关于加压膜的广义平面应变假设We revisit the problem of translation-invariant pressurized membranes that are squeezed without friction between several planes, all parallel to the axis of translation-invariance (such problem involves material and geometric nonlinearities, including contact). Quite remarkably, it was shown by De Simone and Luongo (2013) that such problems simplify considerably under the plane strain assumption. Indeed, the complex initial boundary-value problem reduces to a simple set of non-linear, algebraic equations. We argue that in many practical cases, the plane strain assumption does not hold. Instead, we introduce the generalized plane strain assumption, that is necessary to account for the longitudinal equilibrium of the membrane. We show how the equations of De Simone and Luongo (2013) are modified, while remaining extremely simple. We thus define an extended class of problems that become (nearly) tractable analytically.我们重新探讨了平移不变的受压膜问题，这些膜在多个平面之间受到挤压而没有摩擦，所有平面都平行于平移不变轴（此类问题涉及材料和几何非线性，包括接触）。值得注意的是，De Simone 和 Luongo（2013 年）的研究表明，在平面应变假设下，此类问题大大简化。事实上，复杂的初始边界值问题简化为一组简单的非线性代数方程。我们认为，在许多实际情况下，平面应变假设并不成立。相反，我们引入了广义平面应变假设，这对于解释膜的纵向平衡是必要的。我们展示了 De Simone 和 Luongo（2013 年）的方程是如何被修改的，同时仍然非常简单。因此，我们定义了一类扩展问题，这些问题变得（几乎）可以通过分析解决。Journal of the Mechanics and Physics of SolidsMechanics, modeling, and shape optimization of electrostatic zipper actuatorsAkerson Andrew, Liu Tianshudoi:10.1016/j.jmps.2023.105446静电拉链致动器的力学、建模和形状优化Generating actuation for haptic feedback is a major challenge for wearable devices and soft robotics. Current methods such as piezoelectric, pneumatic, or responsive material actuators are limited by the response time, power consumption, and their reliance on external mechanisms such as pumps or large voltage amplifiers. The emerging technology of electrostatic zipper actuators, where a dielectric-filled pouch is sandwiched between flexible conducting electrodes, is a promising alternative. However, the voltage required to actuate such systems remains in the relatively large kilovolt range. Additionally, there do not currently exist efficient modeling methods to explore more effective designs. Our work looks to address both of these issues. We start by discussing the mechanics of the zipping phenomenon which leads to actuation. Then, we formulate a novel mechanics model for these systems. By considering an elastic plate coupled with the electrostatic interactions, we develop an efficient and robust numerical method to simulate the actuation process. We then verify the model by demonstrating excellent agreement to analytical predictions for simplified cases. As the complex physics of such systems create challenges for intuitive design, we turn to optimal design methods. We formulate the shape optimization problem through the method of mappings to design actuators for maximum actuation pressure and work of actuation. Our method navigates the trade-offs between zipping susceptibility and volume displacement, and we explore optimal designs for various geometric and loading scenarios. Finally, we discuss further directions and open problems relevant to the industrial deployment of zipper actuators moving forward.产生触觉反馈的致动器是可穿戴设备和软机器人技术面临的一大挑战。压电、气动或响应材料致动器等现有方法受限于响应时间、功耗以及对泵或大型电压放大器等外部机制的依赖。新兴的静电拉链致动器技术是一种很有前途的替代方法，这种致动器将充满电介质的小袋夹在柔性导电电极之间。然而，驱动此类系统所需的电压仍然在相对较大的千伏范围内。此外，目前还没有有效的建模方法来探索更有效的设计。我们的工作旨在解决这两个问题。我们首先讨论了导致驱动的拉链现象的力学原理。然后，我们为这些系统制定了一个新颖的力学模型。通过考虑弹性板与静电相互作用的耦合，我们开发了一种高效、稳健的数值方法来模拟致动过程。然后，我们验证了该模型，证明它与简化情况下的分析预测非常吻合。由于此类系统的物理结构复杂，给直观设计带来了挑战，因此我们转向优化设计方法。我们通过映射法来制定形状优化问题，从而设计出最大致动压力和致动功的致动器。我们的方法可以在拉链敏感性和体积位移之间进行权衡，并探索各种几何和负载情况下的最佳设计。最后，我们讨论了与拉链致动器的工业应用相关的进一步方向和未解决问题。Mechanics of MaterialsComposition, heat treatment, microstructure and loading condition based machine learning prediction of creep life of superalloysWu Ronghai, Zeng Lei, Fan Jiangkun, Peng Zichao, Zhao Yunsongdoi:10.1016/j.mechmat.2023.104819基于成分、热处理、微观结构和加载条件的超合金蠕变寿命机器学习预测Creep life is a key property of superalloys that are typically used in advanced engine turbine. The creep life of superalloys is mainly determined by factors including compositions, heat treatment processes, microstructures and loading conditions. Nevertheless, it still remains a big challenge to link these factors and creep life, due to massive variables and complex relations regarding the factors affecting creep life. In the present work, we solve this issue by a machine learning method. The dimension of the factors affecting creep life is reduced by principle component analysis, followed by clustering of the principle components. Then a proper regression method is chose for each cluster such that an optimal model is formed for each cluster. The results show that the predicted creep lives agree with experimental creep lives well. New combinations of composition, heat treatment, microstructure and loading condition with better creep lives are proposed for the development of superalloys. Additionally, the present machine learning method is compared with existing machine learning methods for creep of superalloys. The comparison shows that the accuracy and intelligence of the present machine learning method are both considerably improved. Hence, the present method is useful for effective development of superalloys.蠕变寿命是通常用于先进发动机涡轮的超级合金的一项关键性能。超合金的蠕变寿命主要由成分、热处理工艺、微观结构和加载条件等因素决定。然而，由于影响蠕变寿命的因素存在大量变量和复杂关系，如何将这些因素与蠕变寿命联系起来仍然是一个巨大的挑战。在本研究中，我们通过机器学习方法解决了这一问题。首先通过原理成分分析降低蠕变寿命影响因素的维度，然后对原理成分进行聚类。然后为每个聚类选择适当的回归方法，从而为每个聚类建立一个最佳模型。结果表明，预测的蠕变寿命与实验蠕变寿命非常吻合。为超合金的开发提出了具有更好蠕变寿命的成分、热处理、微观结构和加载条件的新组合。此外，本机器学习方法还与现有的超合金蠕变机器学习方法进行了比较。比较结果表明，本机器学习方法的准确性和智能性都有显著提高。因此，本方法有助于超合金的有效开发。International Journal of PlasticityNegative Stacking Fault Energy in FCC materials-Its ImplicationsYou D., Celebi O., Mohammed ASK., Sehitoglu H.doi:10.1016/j.ijplas.2023.103770催化裂化材料中的负堆积断层能及其影响Recent atomistic simulations on medium entropy alloys uncovered the possibility of negative intrinsic stacking fault energies (SFEs), which suggest infinite stacking fault widths (SFWs). However, experimental measurements of SFWs in the same alloys have shown that SFWs are finite, which contradicts the classical derivations based on force balance. To address this contradiction, we develop an advanced treatment employing atomistic lattice and continuum theories that produce finite SFW solutions corresponding to negative SFEs. The idea is based on energy minimization, where the finite SFW corresponds to the first local minimum in the energy landscape. By exploring combinations of intrinsic and unstable fault energies, we identify regimes in which solutions for finite SFWs exist for thousands of hypothetical materials. Elastic moduli and lattice constants also impact the results, with lower moduli and smaller lattice constants expanding the negative stacking fault energy domain corresponding to finite SFWs. Additionally, the study has revealed a distribution of SFEs due to possible chemical heterogeneities within the alloy, resulting in variations in SFWs within the same material. The work underscores the capabilities of the theory for SFW and CRSS (Critical Resolved Shear Stress) determination for medium to high entropy alloys in agreement with experiments.最近对中等熵合金进行的原子模拟发现了负本征堆积断层能（SFE）的可能性，这表明堆积断层宽度（SFW）是无限的。然而，相同合金中 SFW 的实验测量结果表明，SFW 是有限的，这与基于力平衡的经典推导相矛盾。为了解决这一矛盾，我们开发了一种先进的处理方法，采用原子晶格和连续体理论，产生与负 SFE 相对应的有限 SFW 解决方案。这一想法基于能量最小化，其中有限 SFW 相当于能量景观中的第一个局部最小值。通过探索本征能量和不稳定断层能量的组合，我们确定了数千种假定材料存在有限 SFW 解的情况。弹性模量和晶格常数也会影响研究结果，较低的弹性模量和较小的晶格常数会扩大与有限 SFW 相对应的负堆积断层能量域。此外，研究还揭示了由于合金内部可能存在的化学异质性而造成的 SFE 分布，从而导致同一种材料中 SFW 的变化。这项研究强调了该理论在确定中高熵合金的 SFW 和 CRSS（临界分辨剪切应力）方面的能力，与实验结果一致。Thin-Walled StructuresThermal vibration analysis of cracked nanobeams submerged in elastic foundations by nonlocal continuum mechanicsTaima Moustafa S., El-Sayed Tamer A., Friswell Michael I.doi:10.1016/j.tws.2023.111249利用非局部连续介质力学对浸没在弹性地基中的开裂纳米梁进行热振动分析Understanding the mechanical behavior of nanoscale structures is crucial in the development of advanced nanotechnologies. In this study, a novel approach to investigate the thermal lateral vibration of cracked nanobeams immersed in an elastic matrix is investigated. For this purpose, Reddy’s third-order shear deformation theory (TSDT) is considered. In contrast to Timoshenko beam theory (First-order Shear Deformation Theory, FSDT), TSDT does not depend on a shear correction coefficient. The nano-scale effect is modeled using Eringen’s nonlocal continuum mechanics theory. The nonlocal form of the governing equation is obtained through the application of Hamilton’s principle. The weak form of the finite element global mass and stiffness matrices are obtained using Lagrange linear and Hermitian cubic interpolation. To model the crack in bending vibration, two rotational springs are used for TSDT, unlike the use of a single rotational spring in traditional Bernoulli–Euler (Classical Beam Theory, CBT) and FSDT. The stiffness of the springs is adjusted based on the severity of the crack. The influences of the nonlocal parameter, beam slenderness, position of crack, crack severity, Pasternak and Winkler foundation parameters, thermal effects and boundary conditions on the natural frequencies are investigated. The model’s outcomes are compared with findings from prior publications, demonstrating a strong level of agreement. This study contributes to the growing research on nanostructures by presenting a novel approach to understanding the dynamics of cracked nanobeams using Reddy beam analysis-based solutions.了解纳米级结构的机械行为对于开发先进的纳米技术至关重要。本研究采用一种新方法来研究浸入弹性基质中的开裂纳米梁的热横向振动。为此，考虑了 Reddy 的三阶剪切变形理论（TSDT）。与季莫申科梁理论（一阶剪切变形理论，FSDT）不同，TSDT 不依赖于剪切修正系数。纳米尺度效应使用 Eringen 的非局部连续介质力学理论建模。通过应用汉密尔顿原理，可获得非局部形式的控制方程。有限元全局质量和刚度矩阵的弱形式是通过拉格朗日线性插值和赫尔米特三次插值获得的。与传统的伯努利-欧拉（经典梁理论，CBT）和 FSDT 使用单个旋转弹簧不同，TSDT 使用两个旋转弹簧来模拟弯曲振动中的裂缝。弹簧的刚度根据裂缝的严重程度进行调整。研究了非局部参数、梁的细长度、裂缝位置、裂缝严重程度、帕斯捷尔纳克和温克勒地基参数、热效应和边界条件对固有频率的影响。该模型的结果与之前发表的研究结果进行了比较，结果表明两者具有很高的一致性。这项研究提出了一种新方法，利用基于雷迪梁分析的解决方案来理解开裂纳米梁的动力学，从而为不断增长的纳米结构研究做出了贡献。来源：复合材料力学仿真Composites FEM