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【新文速递】2024年3月19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 1 篇,Thin-Walled Structures 1 篇

Journal of the Mechanics and Physics of Solids

Effect of interphase layer on matrix cracking in fiber reinforced ceramic matrix composites

Xiaochuan Niu, Yong Ma, Shu Guo, Lu Li, Ruixiao Zheng, Jinwu Xiang, Yuli Chen

doi:10.1016/j.jmps.2024.105610

相间层对纤维增强陶瓷基复合材料基体开裂的影响

The onset of matrix steady-state cracking stands as a pivotal mechanical characteristic in fiber reinforced ceramic matrix composites (FRCMCs), garnering substantial attention and investigations. Experimentally, it has been demonstrated that increasing interphase layer thickness may cause non-monotonic changes in matrix cracking stress. However, the existing models can hardly elucidate this phenomenon thoroughly due to the neglect of interphase thickness. This paper presents a comprehensive analytical model for the matrix cracking incorporating interphase, the Poisson effect, Coulomb friction, fiber asperities, residual thermal stress (RTS), and their coupling effects, along with a modified criterion for interfacial debonding that accounts for the presence of the axial RTS. Based on the proposed model, three distinct cracking domains, i.e., perfectly bonded, debonding with and without interfacial separation, have been identified with the critical conditions deduced analytically. Thereby the mechanism of the non-monotonic influence of interphase thickness is thoroughly revealed as the transition of cracking modes. Meanwhile, the role of interphase on the matrix cracking is systematically studied, and the results indicate that interphase has a notable effect through relieving axial RTS, adjusting interfacial friction, altering interfacial shear modulus, and influencing debonding toughness. The outcomes of this study offer valuable guidance for the interphase design of FRCMCs.

基体稳态开裂是纤维增强陶瓷基复合材料(FRCMCs)的一个关键力学特征,引起了大量关注和研究。实验证明,相间层厚度的增加会导致基体开裂应力的非单调变化。然而,由于忽略了相间层厚度,现有模型很难彻底阐明这一现象。本文提出了一种全面的基体开裂分析模型,其中包含相间、泊松效应、库仑摩擦、纤维尖角、残余热应力 (RTS) 及其耦合效应,以及考虑到轴向 RTS 存在的界面脱粘修正准则。根据所提出的模型,确定了三个不同的开裂域,即完全粘合、有界面分离的脱粘和无 界面分离,并通过分析推导出临界条件。由此,彻底揭示了相间厚度非单调影响开裂模式转变的机理。同时,系统研究了相间层对基体开裂的作用,结果表明相间层在缓解轴向 RTS、调节界面摩擦、改变界面剪切模量和影响脱粘韧性等方面具有显著作用。研究结果为 FRCMC 的相间设计提供了宝贵的指导。


Thin-Walled Structures

Energy absorption characteristics of TPMS-filled square tubes under quasi-static axial crushing

Mincen Wan, Dayong Hu, Hongbo Zhang, Zhiqiang Zhang

doi:10.1016/j.tws.2024.111811

TPMS 填充方管在准静态轴向挤压下的能量吸收特性

Taking advantages of thin-walled tubes and triply periodic minimal surface (TPMS) lattices on improving crashworthiness performances, the axial crushing behaviors of square tubes (ST) filled with three types of TPMS lattices (Diamond, Gyroid, and Primitive) were investigated in this study. Specimens made of 316L stainless steel including the empty ST, TPMS lattice fillers, and TPMS-filled ST were additively manufactured and tested under quasi-static axial crushing loads. Meanwhile, the finite element (FE) simulations were verified by the quasi-static experiments, which showed that the experimental curves were well consistent with the simulations. The experimental results also showed that the TPMS-filled ST had more energy absorption capacities (22%-33.7%) compared to the sum of empty ST and TPMS lattice fillers. Furthermore, the influences of relative density (ρ¯), density gradient, unit cell height and multi-morphology hybrid design of TPMS lattice fillers on the energy absorption capacities of TPMS-filled tubes were systematically studied using the validated FE models. The ρ¯ gradient and hybrid design could lead to substantially lower initial peak crushing force (Fp), comparable specific energy absorption (SEA), and larger crushing force efficiency (CFE) compared to uniform counterparts. The TPMS-filled tube with hybrid design of Diamond and Gyroid had at least 16.3% higher SEA compared with other hybrid designs, with the best energy absorption capability. The findings of this paper provided a guidance for the design of thin-walled square tubes filled with TPMS lattices.

本研究利用薄壁管和三重周期性最小表面(TPMS)晶格在提高耐撞性能方面的优势,研究了填充三种 TPMS 晶格(菱形、陀螺形和原始形)的方形管(ST)的轴向挤压行为。由 316L 不锈钢制成的试样(包括空方管、TPMS 晶格填充物和 TPMS 填充方管)经过加成制造,并在准静态轴向挤压载荷下进行了测试。同时,通过准静态实验对有限元(FE)模拟进行了验证,结果表明实验曲线与模拟完全一致。实验结果还表明,与空 ST 和 TPMS 晶格填充物的总和相比,填充 TPMS 的 ST 具有更强的能量吸收能力(22%-33.7%)。此外,利用已验证的有限元模型,系统研究了相对密度(ρ¯)、密度梯度、单胞高度和 TPMS 晶格填料的多形态混合设计对 TPMS 填充管能量吸收能力的影响。与均匀设计的管材相比,ρ¯梯度和混合设计可大大降低初始峰值破碎力(Fp),获得相当的比能量吸收(SEA)和更大的破碎力效率(CFE)。与其他混合设计相比,采用钻石和陀螺混合设计的 TPMS 填充管的 SEA 至少高出 16.3%,能量吸收能力最强。本文的研究结果为填充 TPMS 晶格的薄壁方管的设计提供了指导。




来源:复合材料力学仿真Composites FEM
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首次发布时间:2024-11-13
最近编辑:15天前
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【新文速递】2024年3月25日固体力学SCI期刊最新文章

今日更新:Journal of the Mechanics and Physics of Solids 1 篇,Mechanics of Materials 1 篇,Thin-Walled Structures 1 篇Journal of the Mechanics and Physics of SolidsTop-down constitutive modelling to capture nanoscale shear localizationJici Wen, Yujie Weidoi:10.1016/j.jmps.2024.105629 捕捉纳米级剪切定位的自顶向下构造模型Deformation localization as exemplified by earthquakes, landslides, shear banding in solids, and failure of engineering components is of utmost importance. In practice, differentiating the mechanical behavior in such generative narrow bands from the rest part, with difference by orders of magnitude in characteristic size, flow strength, temperature, and shearing rate, is both experimentally and computationally formidable. Here we propose a machine-learning-based constitutive modeling framework to overcome this barrier borne from conventional top-down continuum modelling approach. The model enables us to realize ultra-fine resolutions for deformation in those narrow bands with high efficiency. Taking metallic glasses (MGs) as an example, our model captures well shear localization in BMGs across a broad range of temperatures (0 K to its melting point of ∼1000 K) and strain rates (10^−4 to 10^8/s). We verify through this model the width of shear bands (SBs) in MGs is on the order of 5 to 8 nanometers, which is resulted from a cascade of (intervening) events, from localized shearing to plastic heating, subsequent temperature rise to thermal softening, and accelerated flow rate to strain-rate hardening. Temperature rise in SBs is a resultant of heat flow and plastic dissipation, but strongly depend on thermal conductivity: Low thermal conductivity facilitates strain localization and great temperature rise. It explains the current controversy upon experimentally measured temperature rise ranging from several K to ∼1000 K. Lastly, strain rates within SBs are approximately one to two orders of magnitude higher than externally applied strain rates, and in general shearing in adiabatic SBs is faster than that in isothermal condition.地震、山体滑坡、固体中的剪切带以及工程部件的失效所体现的变形局部化至关重要。在实践中,要将这种产生窄带的机械行为与其他部分区分开来,在特征尺寸、流动强度、温度和剪切速率等方面存在数量级的差异,这在实验和计算上都是非常困难的。在此,我们提出了一种基于机器学习的结构建模框架,以克服传统的自上而下连续建模方法所带来的障碍。该模型使我们能够高效地实现窄带变形的超精细分辨率。以金属玻璃(MGs)为例,我们的模型能很好地捕捉到 BMGs 在宽温度范围(0 K 至其熔点 ∼1000 K)和应变速率(10^-4 至 10^8/s)内的剪切定位。我们通过该模型验证了MGs中剪切带(SBs)的宽度约为5至8纳米,它是由一连串(相互干扰的)事件造成的,从局部剪切到塑性加热,随后的温度上升到热软化,以及流速加快到应变速率硬化。SB 中的温升是热流和塑性耗散的结果,但在很大程度上取决于热传导率: 低导热率有利于应变局部化和大幅温升。最后,SBs 内部的应变速率比外部施加的应变速率高出约一到两个数量级,一般来说,绝热 SBs 中的剪切比等温条件下的剪切更快。Mechanics of MaterialsMolecular insights into reversible and irreversible kinks formed in nanocelluloseRongZhuang Song, YuanZhen Hou, ZeZhou He, HengAn Wu, YinBo Zhudoi:10.1016/j.mechmat.2024.104986 对纳米纤维素中形成的可逆和不可逆扭结的分子认识Kink defects in nanocellulose are common, yet questions remain open regarding the unclear microstructure-mechanical property relationship. Various kink patterns without molecular-scale resolution cause confusion about how nanocellulose forms different kinks and what the fundamental mechanisms of reversible and irreversible kinks are. In atomic force microscopy images, bent nanofibrils usually exhibit small curvatures, while kinked nanofibrils feature sharp bends, in which kinks are notable due to their distinct disordered configurations. To identify the incipient kink defects formed in nanocellulose, molecular dynamics simulations of cellulose nanocrystals (CNCs) under curvature-dependent bending were subsequently carried out. Five typical bending/kinking modes were found, depending on the anisotropic microstructure and size of CNCs. More importantly, two contrasting cases of kinks were demonstrated, providing evidence that kink defects in nanocellulose depend mainly on the microstructure at the molecular scale. Kinks in CNCs with the (100) and (11¯0) crystal plane are recoverable with a few residual defects. While kinks in CNCs with the (010) crystal plane are irreversible with permanent microstructural damage. Compressive stresses accumulated in the bottom chains of CNC contribute to the main mechanism for forming incipient kinks in nanocellulose. The results can fundamentally answer the confusion in recent experiments why bond breakage did not necessarily occur even at high kink angles. The insights present intrinsic deformation mechanisms for understanding the widespread but mysterious kinks arising in nanocellulose.纳米纤维素中的扭结缺陷很常见,但微观结构与力学性能之间的关系尚不明确,因此问题仍然存在。没有分子尺度分辨率的各种扭结模式使人们对纳米纤维素如何形成不同的扭结以及可逆和不可逆扭结的基本机制感到困惑。在原子力显微镜图像中,弯曲的纳米纤维通常表现出较小的曲率,而扭结的纳米纤维则以急剧弯曲为特征,其中扭结因其独特的无序构型而引人注目。为了确定纳米纤维素中形成的初期扭结缺陷,随后对纤维素纳米晶体(CNC)在曲率依赖性弯曲条件下进行了分子动力学模拟。根据各向异性的微观结构和 CNC 的尺寸,发现了五种典型的弯曲/扭结模式。更重要的是,研究发现了两种截然不同的扭结情况,从而证明纳米纤维素中的扭结缺陷主要取决于分子尺度上的微观结构。晶面为 (100) 和 (11¯0) 的 CNC 中的扭结可恢复,但残留缺陷较少。而(010) 晶面的 CNC 中的扭结是不可逆的,会造成永久性的微观结构破坏。在 CNC 底链中积累的压应力是纳米纤维素形成初期扭结的主要机制。这些结果从根本上解答了近期实验中的一个困惑,即为什么即使在高扭结角下也不一定会发生键断裂。这些见解提出了内在的变形机制,有助于理解纳米纤维素中广泛存在但却神秘莫测的扭结现象。Thin-Walled StructuresExperimental and numerical study of impact resistance and compression properties after impact of none-felt needled compositesTianlei Yao, Jiao Li, Xiaoming Chen, Diansen Li, Lei Jiangdoi:10.1016/j.tws.2024.111807非毛毡针 刺复合材料抗冲击性和冲击后压缩性能的实验与数值研究In this paper, the impact and after-impact compression (CAI) properties of new none-felt needled composites were investigated by finite element and experimental methods. Micro-CT and digital image correlation (DIC) were used for structural characterization and recording surface strains in CAI specimens. The impact and CAI finite element models of needled composites were developed, and the damage mechanisms were analyzed. The results showed that the impact and CAI properties of none-felt needled composite were substantially improved. In the impact experiments, the failure firstly occurred in the interlayer and gradually extended to the fiber layer. In the CAI experiment, the damage gradually extended from the impact damage region to the specimen edges, and the specimen finally failed when the damage with the specimen edges extended together. The established finite element model agreed well with both the impact and CAI tests, and the errors were less than 5% and 10%.本文采用有限元和实验方法研究了新型非毛毡针 刺复合材料的冲击和冲击后压缩(CAI)性能。微计算机断层扫描和数字图像相关(DIC)被用于 CAI 试样的结构表征和表面应变记录。建立了针 刺复合材料的冲击和 CAI 有限元模型,并分析了其损伤机理。结果表明,非毛毡针 刺复合材料的冲击和 CAI 性能得到了显著改善。在冲击实验中,破坏首先发生在夹层,然后逐渐扩展到纤维层。在 CAI 实验中,损伤从冲击损伤区域逐渐扩展到试样边缘,当损伤与试样边缘一起扩展时,试样最终失效。建立的有限元模型与冲击试验和 CAI 试验结果吻合良好,误差分别小于 5%和 10%。来源:复合材料力学仿真Composites FEM

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