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【新文速递】2024年10月18日固体力学SCI期刊最新文章

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今日更新:International Journal of Solids and Structures 1 篇,Mechanics of Materials 3 篇,Thin-Walled Structures 5 篇

International Journal of Solids and Structures

An optimal penalty method for the joint stiffening in beam models of additively manufactured lattice structures

T. Cadart, T. Hirschler, S. Bahi, S. Roth, F. Demoly, N. Lebaal

doi:10.1016/j.ijsolstr.2024.113107

增材制造晶格结构梁模型中节点加劲的最优惩罚方法

Additive manufacturing is revolutionizing structural design, with lattice structures becoming increasingly prominent due to their superior mechanical properties. However, simulating these structures quickly and accurately using the finite element method (FEM) remains challenging. Recent research has highlighted beam element simulation within FEM as a more efficient alternative to traditional solid FE simulations, achieving similar accuracy with reduced computational resources. However, a significant challenge is managing the lack of rigidity at nodes and the prevalence of low aspect ratio beams. While various methodologies have been proposed to address these issues, there is still a gap in the comprehensive evaluation of their limitations. An optimal node penalization methodology is required to expand the limited range of accurately represented lattice behavior. A preliminary study investigates lattice geometries through comparative analysis of solid and beam FE simulations. Built on this, we developed a methodology suitable to linear, dynamics and nonlinear beam FE simulations, contributing to enhanced computational speed and accuracy. Several lattice structures were printed using material jetting and quasi-static compressive tests were conducted to validate the methodology’s accuracy. The numerical results reveal a good accuracy between the proposed beam FE methodology and the experimental data, offering a better alternative to conventional FEM for energy absorption in terms of computing time.

增材制造正在彻底改变结构设计,晶格结构由于其优越的机械性能而变得越来越突出。然而,使用有限元方法快速准确地模拟这些结构仍然具有挑战性。最近的研究强调,有限元中的梁单元模拟是传统实体有限元模拟的更有效的替代方法,可以在减少计算资源的情况下达到相似的精度。然而,一个重大的挑战是管理节点缺乏刚度和低纵横比梁的流行。虽然提出了各种方法来解决这些问题,但在全面评价其局限性方面仍然存在差距。需要一种最优节点惩罚方法来扩展精确表示晶格行为的有限范围。通过对固体和梁有限元模拟的对比分析,初步研究了晶格几何形状。在此基础上,我们开发了一种适用于线性,动态和非线性梁有限元模拟的方法,有助于提高计算速度和准确性。利用材料喷射和准静态压缩实验验证了该方法的准确性。数值结果表明,所提出的梁有限元方法与实验数据具有较好的准确性,在计算时间上优于传统有限元方法。


Mechanics of Materials

Experimental and digital twinning in ZnAlMg coatings

Ahmed Zouari, Mikel Bengoetxea-Aristondo, Filip Siska, Aymen Bouzid, Fabrice Gaslain, Aurélien Chopin, Houssem Eddine Chaieb, Kais Ammar, Pascal Bertho, Joost De Strycker, Jean-Michel Mataigne, Samuel Forest

doi:10.1016/j.mechmat.2024.105173

ZnAlMg涂层的实验孪生和数字孪生

Twinning is a major deformation mechanism in various materials, especially when few dislocation slip systems are operative. It is the case of zinc-rich coatings in galvanised steel sheets, made of pancake grains on a substrate and where the slip systems with a non-vanishing component along the c -axis present high critical resolved shear stress values. In addition, the abrupt lattice orientation change associated to twinning, the stress relaxation during its propagation and the localised nature of its early stages make it difficult to reproduce this deformation mechanism by using classical crystal plasticity models conceived for dislocation slip. In this sense, this work proposes a hierarchy of three twinning models in combination with a dislocation slip crystal plasticity model, for the case of a ZnAlMg coating. These three models are: a relaxed-Taylor model applied to individual crystal orientations of the coating, a “pseudo-slip” model for twinning and a localised twinning model. The latter incorporates a linear softening in the material law accounting for the unstable twinning initiation and enforces twinning lattice reorientation. A microstructure portion extracted from an in-situ SEM tensile experiment on galvanised steel is used to perform 3D full-field finite element simulations within a finite strain formulation. SEM observations and EBSD acquisitions are used to compare simulation and experimental results during the different steps of the in-situ SEM test, regarding the deformation and damage modes of the zinc-rich coating. The focus is set on twinning evolution inside some individual grains, and the pros and the cons of the three models are finally discussed.

孪生是各种材料的主要变形机制,特别是在少数位错滑移系统起作用时。这是镀锌钢板上的富锌涂层的情况,由基底上的煎饼颗粒制成,其中沿c轴具有不消失成分的滑移系统呈现高临界分解剪切应力值。此外,与孪晶相关的晶格取向突变、孪晶传播过程中的应力松弛以及早期阶段的局域性,使得用位错滑移的经典晶体塑性模型难以再现这种变形机制。从这个意义上说,本工作提出了三个孪生模型的层次结构,并结合了ZnAlMg涂层的位错滑移晶体塑性模型。这三种模型是:一种适用于涂层单个晶体取向的松弛泰勒模型,一种用于孪生的“伪滑移”模型和一种局部孪生模型。后者在材料律中包含线性软化,用于解释不稳定的孪晶起始并强制孪晶晶格重定向。从镀锌钢的原位扫描电镜拉伸实验中提取的微观结构部分用于在有限应变公式内进行三维全场有限元模拟。通过SEM观察和EBSD采集,对比了原位SEM测试不同步骤的模拟结果和实验结果,研究了富锌涂层的变形和损伤模式。重点讨论了个别晶粒内部的孪晶演化,并讨论了三种模型的优缺点。


The influences of temperature on the macroscopic elastoplastic behaviors of heterogeneous materials

W.Q. Shen

doi:10.1016/j.mechmat.2024.105176

温度对非均质材料宏观弹塑性行为的影响

The microstructure of heterogeneous materials affectes importantly their macroscopic mechanical behavior. For a thermal-mechanical coupling problem, the temperature also has a significant effect. Firstly, the effect of temperature on the elastic behavior of heterogeneous material has been investigated in the present work with the consideration of its microstructure. Then, an explicit expression of the macroscopic yield criterion has been derived for the plastic behavior of porous material by using the homogenization approach. This yield criterion takes into account explicitly and simultaneously the influence of porosity and the effect of temperature on its overall mechanical behavior. To consider the pressure sensitivity of the matrix, the Drucker–Prager type criterion is adopted at the microscopic scale. After that, the heterogeneous material with a matrix reinforced by rigid inclusions has been studied. The microstructure information, such as the inclusion content, matrix property and the temperature have been considered explicitly in the obtained yield function. The influences of temperature and the confining pressure on the macroscopic material strength are captured by the obtained criterion. Then, the obtained result is applied to describe the temperature-dependent mechanical behaviors of sandstone.

非均相材料的微观结构对其宏观力学行为有重要影响。对于热-力耦合问题,温度也有显著的影响。本文首先从微观结构出发,研究了温度对非均质材料弹性行为的影响。然后,利用均匀化方法导出了多孔材料塑性行为的宏观屈服准则的显式表达式。该屈服准则明确地同时考虑了孔隙率和温度对其整体力学行为的影响。为了考虑基质的压力敏感性,在微观尺度上采用Drucker-Prager型判据。在此基础上,研究了由刚性夹杂物增强基体的非均质材料。得到的屈服函数明确考虑了夹杂物含量、基体性质和温度等微观结构信息。所得准则反映了温度和围压对材料宏观强度的影响。然后,将所得结果应用于描述砂岩随温度变化的力学行为。


Thermalized and mixed meanfield ADP potentials for magnesium hydrides

M. Molinos, M. Ortiz, M.P. Ariza

doi:10.1016/j.mechmat.2024.105175

氢氧化镁的热化和混合平均场ADP电位

We develop meanfield approximation and numerical quadrature schemes for the evaluation of Angular-Dependent interatomic Potentials (ADPs) for magnesium and magnesium hydrides at finite temperature (thermalization) and arbitrary atomic molar fractions (mixing) within a non-equilibrium statistical mechanical framework and derive local equilibrium relations. We numerically verify and experimentally validate the accuracy and fidelity of the resulting thermalized/mixed ADPs (TADPs) by means of selected numerical tests including free entropy, heat capacity, thermal expansion, molar volumes, equation of state and elastic constants. We show that the local equilibrium properties predicted by TADPs agree closely with those computed directly from ADP by means of Molecular Dynamics (MD).

在非平衡统计力学框架下,我们开发了平均场近似和数值正交方案,用于评估镁和氢化物在有限温度(热化)和任意原子摩尔分数(混合)下的角依赖原子间势(ADPs),并推导了局部平衡关系。通过自由熵、热容、热膨胀、摩尔体积、状态方程和弹性常数等数值测试,对所得的热化/混合ADPs (TADPs)进行了数值验证和实验验证。结果表明,用TADPs预测的局部平衡性质与用分子动力学(MD)直接从ADP计算的结果非常吻合。


Thin-Walled Structures

Unraveling anisotropic mechanical behaviors of lithium-ion battery separators: Microstructure insights

Zhiwei Hao, You Gao, Ji Lin, Lubing Wang

doi:10.1016/j.tws.2024.112593

揭示锂离子电池隔膜的各向异性力学行为:微观结构的见解

The mechanical properties of separators significantly affect the electrochemical stability and potential short circuit risks in lithium-ion batteries. An important aspect of their mechanical behavior is their anisotropy, which is predominantly influenced by the microstructures formed during manufacturing process. This study aims to bridge the gap between the anisotropic mechanical features of the separators and their microstructures caused by the manufacturing methods. Initially, we delve into the characterization of separators, featuring their heterogeneous components and orientated arrangement of fibers. Then, we conduct uniaxial tensile tests to measure the stress-strain relationships of separators along the machine direction (MD), diagonal direction (DD), and transverse direction (TD), revealing pronounced anisotropy in both strength and rate sensitivity. Subsequently, image processing techniques is adopted to obtain a representative configuration of separators, which is further divided into fibers and lamellae. According to the manufacturing process of separators, a viscoplastic model is used to describe the mechanical behavior of lamellae while a strengthened viscoplastic model is utilized to mimic the mechanical response of fibers. The finite element analyses underscore the dominant role of orientated fibers in determining anisotropic mechanical properties. Furthermore, we explore the effects of manufacturing and geometry parameters on the separator's anisotropic mechanical behavior. This research provides valuable insights for optimizing manufacturing parameters and enhancing safety measures for lithium-ion batteries.

隔膜的力学性能对锂离子电池的电化学稳定性和潜在短路风险有重要影响。其力学行为的一个重要方面是它们的各向异性,这主要受制造过程中形成的微观组织的影响。本研究旨在弥补由于制造方法造成的隔膜的各向异性力学特性与微观结构之间的差距。首先,我们深入研究了隔膜的特性,包括它们的异质成分和纤维的定向排列。然后,我们进行了单轴拉伸试验,以测量沿机器方向(MD),对角线方向(DD)和横向方向(TD)的应力-应变关系,揭示了强度和速率敏感性的明显各向异性。随后,采用图像处理技术得到具有代表性的隔膜结构,并将其进一步划分为纤维和片层。根据分离机的制造过程,采用粘塑性模型来描述片层的力学行为,采用强化粘塑性模型来模拟纤维的力学响应。有限元分析强调了取向纤维在确定各向异性力学性能方面的主导作用。此外,我们还探讨了制造参数和几何参数对分离器各向异性力学行为的影响。该研究为优化锂离子电池的制造参数和加强安全措施提供了有价值的见解。


Damage behavior of composite honeycomb sandwich structure subject to low-velocity impact and compression-after-impact using experimental and numerical methods

Wanhui Ma, Hongliang Tuo, Qingtian Deng, Xinbo Li

doi:10.1016/j.tws.2024.112594

基于实验和数值方法的复合材料蜂窝夹层结构低速冲击和后冲击压缩损伤行为

The paper studies the damage initiation and evolution of composite honeycomb sandwich structure subject to low-velocity impact and CAI (compression after impact) loadings by a combination of experimental and numerical methods. The impact responses including impact force and energy absorption were obtained through impact tests, and detailed damage analysis was conducted using various testing methods including ultrasonic C-scan, DIC (digital image correlation), infrared thermography and SEM (scanning electron microscope). A damage model based on MMF (micro-mechanics of failure) and cohesive behavior were used to predict the mechanical behavior of composite facesheets, and an elastoplastic constitutive model with ductile damage was used to model the honeycomb core. The experimental and numerical results show good agreements and reveal that the matrix damage, delamination, core crushing and fiber damage will be induced in the composite honeycomb sandwich structure depending on the impact energy levels. During the CAI process, the strain concentration in the impact region will lead to local buckling of the sandwich structure, and the damage expands from the impact region to the free edges along the transverse direction until the final collapse, which will cause an obvious temperature increase in the damage area.

采用实验与数值相结合的方法,研究了复合材料蜂窝夹层结构在低速冲击和冲击后压缩载荷作用下的损伤起裂与演化过程。通过冲击试验获得了包括冲击力和能量吸收在内的冲击响应,并采用超声c扫描、DIC(数字图像相关)、红外热像仪和SEM(扫描电镜)等多种测试方法对其进行了详细的损伤分析。采用基于微破坏力学(MMF)和内聚行为的损伤模型预测复合材料面板的力学行为,采用含延性损伤的弹塑性本构模型模拟蜂窝芯。实验结果与数值计算结果吻合较好,表明不同的冲击能级会诱发复合材料蜂窝夹层结构的基体损伤、分层、芯层破碎和纤维损伤。在CAI过程中,冲击区域的应变集中会导致夹层结构局部屈曲,损伤沿横向方向从冲击区域向自由边缘扩展,直至最终坍塌,从而导致损伤区域温度明显升高。


A one-time training machine learning method for general structural topology optimization

Sen-Zhen Zhan, Xinhong Shi, Xi-Qiao Feng, Zi-Long Zhao

doi:10.1016/j.tws.2024.112595

用于一般结构拓扑优化的一次性训练机器学习方法

Machine learning (ML) methods have found some applications in structural topology optimization. In the existing methods, however, the ML models need to be retrained when the design domains and supporting conditions have been changed, posing a limitation to their wide applications. In this paper, we propose a one-time training ML (OTML) method for general topology optimization, where the self-attention convolutional long short-term memory (SaConvLSTM) model is introduced to update the design variables. An extension–division approach is used to enrich the training sets. By developing a splicing strategy, the training results of a small design space (i.e., a basic cell of either two- or three-dimensions) can be extended to tackling the optimization problem of a large design domain with arbitrary geometric shapes. Using the OTML method, the ML model needs to be trained for only one time, and the trained model can be used directly to solve various optimization problems with arbitrary shapes of design domains, loads, and boundary conditions. In the SaConvLSTM model, the material volume of the post-processed thresholded designs can be precisely controlled, though the control precision of the gray-scale designs might be slightly sacrificed. The effects of model parameters on the computational cost and the result quality are examined. Four examples are provided to demonstrate the high performance of this structural design method. For large-scale optimization problems, the present method can accelerate the structural form-finding process. This study holds a promise in the high-resolution structural form-finding and transdisciplinary computational morphogenesis.

机器学习方法在结构拓扑优化中有一定的应用。然而,在现有方法中,当设计领域和支持条件发生变化时,需要对机器学习模型进行重新训练,这限制了其广泛应用。在本文中,我们提出了一种用于一般拓扑优化的一次性训练机器学习(OTML)方法,其中引入自注意卷积长短期记忆(SaConvLSTM)模型来更新设计变量。采用可拓划分方法丰富训练集。通过开发一种拼接策略,可以将小设计空间(即二维或三维的基本单元)的训练结果扩展到具有任意几何形状的大设计域的优化问题。使用OTML方法,只需要对ML模型进行一次训练,训练后的模型可以直接用于解决具有任意形状的设计域、载荷和边界条件的各种优化问题。在SaConvLSTM模型中,后处理阈值设计的材料体积可以得到精确控制,但灰度设计的控制精度可能会有所牺牲。考察了模型参数对计算成本和结果质量的影响。通过四个算例验证了该结构设计方法的有效性。对于大规模优化问题,该方法可以加快结构寻形过程。该研究在高分辨率结构形态发现和跨学科计算形态发生方面具有前景。


Bearing and tearout of austenitic and duplex stainless steel bolted connections

Yuchen Song, Xue-Mei Lin, Michael C.H. Yam, Yuelin Zhang, Ke Ke, Jia Wang

doi:10.1016/j.tws.2024.112585

奥氏体和双相不锈钢螺栓连接的轴承和拆卸

Due to the unique material characteristics of stainless steel, the bearing and tearout behaviour of stainless steel bolted connections can be different from that of carbon steel bolted connections. Such difference has been gradually recognised in recent design provisions for stainless steel structures. However, it is noteworthy that the existing design methods were mainly developed for austenitic and ferritic stainless steel bolted connections. Their applicability to duplex stainless steel bolted connections is questionable. Moreover, comparing to the bearing failure of stainless steel connections, less attention has been paid to the tearout failure, as well as the combined bearing and tearout failure in multi-bolt connections. To fill these gaps, an experimental and numerical study is carried out on the bearing/tearout behaviour and design of stainless steel bolted connections. The experimental programme includes 22 connection specimens with either single-bolt or multi-bolt configurations, made of austenitic or duplex stainless steel. The experimental tests are supplemented by a comprehensive numerical parametric study with more than 200 individual models, performed based on a validated finite element modelling technique. The obtained test and numerical results are used to assess the effects of different design parameters, as well as the applicability of existing design methods. It is concluded that the ultimate bearing/tearout resistances of austenitic and duplex connections are not simply proportionate to the ultimate strengths of the two materials. Given the same geometric design, the bearing resistance of a duplex connection is considerably higher than that of an austenitic connection, despite the similar ultimate strengths of the two materials. This difference in bearing performance is attributed to the different strain-hardening characteristics of austenitic and duplex materials, as well as the premature shear cracking in austenitic connections that leads to insufficiently developed strain-hardening. In comparison, the tearout resistances of austenitic and duplex connections with the same geometry are much closer, since the smaller end distance leads to more uniform deformations and more completely developed strain-hardening. Moreover, the combined bearing and tearout resistance of multi-bolt connections is found to be lower than the sum of the respective resistances of individual bolts. Finally, an updated design method is proposed that can accurately predict the bearing/tearout resistance of both austenitic and duplex stainless steel bolted connections. Proper partial factors are determined for the proposed method based on a reliability analysis.

由于不锈钢独特的材料特性,不锈钢螺栓连接的承载和撕裂行为可能与碳钢螺栓连接不同。这种差异在最近的不锈钢结构设计规定中已逐渐被认识到。但值得注意的是,现有的设计方法主要是针对奥氏体和铁素体不锈钢螺栓连接开发的。它们对双相不锈钢螺栓连接的适用性值得怀疑。此外,与不锈钢连接的轴承失效相比,对拆出失效以及多螺栓连接的轴承和拆出组合失效的关注较少。为了填补这些空白,对不锈钢螺栓连接的承载/撕裂性能和设计进行了试验和数值研究。试验方案包括22个连接试件,采用单螺栓或多螺栓配置,由奥氏体或双相不锈钢制成。实验测试是由一个全面的数值参数研究,超过200个单独的模型,基于验证的有限元建模技术进行的补充。利用试验结果和数值计算结果对不同设计参数的影响以及现有设计方法的适用性进行了评价。由此得出结论,奥氏体连接和双相连接的极限承载/抗撕裂性能并不简单地与两种材料的极限强度成正比。在相同的几何设计下,尽管两种材料的极限强度相似,但双相连接的承载阻力要比奥氏体连接高得多。这种承载性能的差异是由于奥氏体和双相材料的应变硬化特性不同,以及奥氏体连接中的过早剪切开裂导致应变硬化不充分发展。相比之下,具有相同几何形状的奥氏体和双相连接的抗撕裂性更接近,因为较小的端距导致更均匀的变形和更完全的应变硬化。此外,发现多螺栓连接的联合承载和撕裂阻力小于单个螺栓各自的阻力之和。最后,提出了一种更新的设计方法,可以准确预测奥氏体和双相不锈钢螺栓连接的承载/撕裂阻力。在可靠性分析的基础上,确定了该方法的适当偏因子。


Development of self-centring beam-to-column joints with large-dimensional SMA buckling-restrained plates

Zhi-Peng Chen, Songye Zhu

doi:10.1016/j.tws.2024.112586

大尺寸SMA抗屈曲板自定心梁柱节点的研制

This paper presents an innovative self-centring beam-to-column joint (SC-BCJ) design that utilises shape-memory alloy (SMA) plates. The proposed SMA-SC-BCJ is constructed through a straightforward approach using large-scale SMA plates to concentrate inelastic deformation and achieve self-centring (SC) capability. This paper first introduces the components and configuration of SMA-SC-BCJ, followed by the development of a refined finite element model for simulations. Validation against previous experiments verifies the model accuracy in capturing joint behaviour. The analysis shows SMA-SC-BCJ exhibits desirable flag-shaped hysteretic behaviours with excellent SC capability, achieving approximately 92% recovery alongside moderate energy dissipation. Substantial inelastic deformation localises in the SMA fuse plate due to joint rocking, with minimal plastic strain around the rocking centre. Parametric studies on shear element construction, bolt pretension levels and beam gap distances provide additional insights into the joint design. The proposed design meets the objectives for a minimal-damage beam-to-column joint with a simple construction. The SMA-SC-BCJ design recommendations are presented on the basis of performance assessments, elucidating the effectiveness of the system. This work contributes an innovative seismic-resistant joint solution that advances the emerging practices towards resilient structures.

本文提出了一种利用形状记忆合金(SMA)板的创新自中心梁柱节点(SC-BCJ)设计。所提出的SMA-SC- bcj是通过一种简单的方法构建的,使用大规模SMA板来集中非弹性变形并实现自定心(SC)能力。本文首先介绍了SMA-SC-BCJ的组成和结构,然后建立了精细化的有限元模型进行仿真。通过对先前实验的验证,验证了模型在捕获关节行为方面的准确性。分析表明,SMA-SC-BCJ具有良好的旗形滞回性能,具有优异的SC性能,在适度耗能的同时实现了约92%的恢复。大量的非弹性变形在SMA保险丝板局部由于接头的摇摆,与最小的塑性应变周围的摇摆中心。剪切单元结构、螺栓预紧水平和梁间隙距离的参数化研究为节点设计提供了额外的见解。提出的设计方案满足了梁柱节点损伤最小、结构简单的目标。在性能评估的基础上提出了SMA-SC-BCJ设计建议,阐明了系统的有效性。这项工作为创新的抗震接缝解决方案做出了贡献,推动了新兴的弹性结构实践。



来源:复合材料力学仿真Composites FEM
ACTMechanicalAdditiveSystemDeform复合材料非线性化学拓扑优化增材材料分子动力学数字孪生控制试验螺栓
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【新文速递】2024年10月23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,Thin-Walled Structures 5 篇Journal of the Mechanics and Physics of SolidsElastoplastic plate shakes down under repeated impulsive loadingsZengshen Yue, Bingyang Li, Xin Wang, Zhen Li, Rui Zhang, Pengfei Wang, Li Cheng, Tian Jian Ludoi:10.1016/j.jmps.2024.105918弹塑性板在反复的脉冲载荷作用下会发生振动When subjected to repeated dynamic impacts at identical load level, a metallic monolithic beam/plate may reach a stable state wherein measurable deformation ceases (i.e., shakedown in elastic state) after undergoing a sequence of elastoplastic deformations, which has been termed as “pseudo-shakedown” (P-S) (Jones, 1973, Shen and Jones, 1992). While the response of a single beam/plate under repeated low-velocity impacts has been thoroughly studied, its dynamic behavior under high-velocity impacts, such as explosive or alternating impulsive loads, is difficult to measure experimentally, due mainly to high costs and setup challenges. In the current study, the method of metallic foam projectile impact was employed to produce repeated impulsive loadings on a fully-clamped elastoplastic monolithic plate made of L907A (a Chinese standard shipbuilding steel). Its dynamic responses, including mid-point deflection versus time histories, final deflections, and deformation modes after each impact, were systematically measured. The phenomenon of dynamic shakedown was observed. To further explore this phenomenon, the method of finite elements (FE) was employed to simulate the repeated impulsive impact test, and its prediction accuracy was validated against experimental results. Unlike an elastoplastic (e.g., steel) monolithic plate subjected to repeated low-velocity impacts, which exhibits zero plastic energy dissipation in the P-S (pseudo-shakedown) state, the same plate under repeated high-velocity impacts shows a small level of plastic energy dissipation in the P-S state, mainly due to more extreme loading conditions. The initial impact momentum, yield strength, and tangent modulus of the material the plate is made of significantly affect both the stable deflection in the P-S state and the number of impacts needed to reach it, while the elastic modulus has limited influence. A modified dimensionless impulse loading number, accounting for the strain-hardening effect, is proposed. An approximately linear relationship between stable deflection in the P-S state and impulsive loading is found in dimensionless form.当金属整体梁/板在相同的荷载水平上受到反复的动力冲击时,在经历了一系列弹塑性变形后,金属整体梁/板可能达到稳定状态,其中可测量的变形停止(即弹性状态下的安定),这种变形被称为“伪安定”(P-S) (Jones, 1973; Shen和Jones, 1992)。虽然单梁/板在重复低速冲击下的响应已经得到了深入的研究,但由于高成本和设置挑战,其在高速冲击(如爆炸或交变脉冲载荷)下的动态行为难以通过实验测量。在本研究中,采用金属泡沫弹丸冲击的方法,对L907A(中国标准造船钢)全夹紧弹塑性整体板产生重复脉冲载荷。系统地测量了其动态响应,包括中点挠度与时间历史、最终挠度和每次撞击后的变形模式。观察到动态安定现象。为了进一步探讨这一现象,采用有限元方法对重复脉冲冲击试验进行了模拟,并与试验结果对比验证了预测的准确性。弹塑性(如钢)整体板在重复低速冲击下,在P-S(伪安定)状态下表现为零塑性能量耗散,而同一块板在重复高速冲击下,在P-S状态下表现出很小的塑性能量耗散,这主要是由于更极端的加载条件。板材的初始冲击动量、屈服强度和切线模量对P-S状态下的稳定挠度和达到稳定挠度所需的撞击次数都有显著影响,而弹性模量的影响有限。提出了考虑应变硬化效应的改进无量纲冲击载荷数。在无量纲形式下,发现P-S状态下的稳定挠度与脉冲载荷之间存在近似线性关系。Thin-Walled StructuresStudy on the buckling behavior of aluminum alloy sheets - before and after repaired with composite patchesXin Li, Anbiao Zhong, Jiale Zhang, Weilin Dong, Ruoqin Xiong, Heng Zhang, Xiaoliang Geng, Lei Huang, Jun Liudoi:10.1016/j.tws.2024.112614复合修补前后铝合金板的屈曲行为研究In this paper, the compressive buckling behavior of aluminum alloy plates with an elliptical hole of various sizes is investigated. In order to improve the stability of these thin plates, T700/QY8911 composite laminate is used as a patch to repair the hole. The study included an analysis of the critical and post-critical behaviour using experimental and numerical methods. Experiments focus on buckling loads, post-buckling behavior and the relationship between sizes of holes and buckling load. Meanwhile, the buckling load and buckling mode are determined by finite element analysis, using linear analysis of eigenvalue problems modes, and then, the nonlinear analysis of structures with initiated geometrically imperfection is carried out, studying its post-buckling behavior, damage behavior and transfer of load. The results show that the buckling load of the open-hole specimen is related to size of opening. The existence of patch has a significant influence on stress distribution, and the buckling capability of repaired specimens is noticeably improved to the plate without a hole. And the compression experimental results are consistent with the numerical results, revealing that the developed finite element model of the structure is correct.本文研究了不同尺寸椭圆孔铝合金板的压缩屈曲行为。为了提高这些薄板的稳定性,采用T700/QY8911复合层压板作为补片修补孔洞。该研究包括使用实验和数值方法对临界和后临界行为进行分析。实验重点研究了屈曲载荷、后屈曲行为以及孔洞尺寸与屈曲载荷的关系。同时,通过有限元分析,利用特征值问题模态的线性分析,确定了结构的屈曲载荷和屈曲模态,并对具有初始几何缺陷的结构进行了非线性分析,研究了结构的失稳后行为、损伤行为和载荷传递。结果表明:开孔试件的屈曲载荷与开孔尺寸有关。补片的存在对应力分布有显著影响,修复试件的屈曲能力明显优于无孔板。压缩实验结果与数值计算结果吻合较好,表明所建立的结构有限元模型是正确的。Peridynamics model of torsion-warping: Application to lattice beam structuresSajal, Pranesh Roydoi:10.1016/j.tws.2024.112603 扭转翘曲的周动力学模型:在点阵梁结构中的应用This paper presents a finite deformation beam model based on Simo-Reissner theory in peridynamics (PD) framework to deal with torsion induced warping deformation. Seven degrees of freedom, viz. three translational, three rotational, and one warping amplitude are considered at each material point. The governing equations of the beam are obtained by employing global balance of linear and angular momenta in conjunction with Simo's assumption on the deformation field. The relation between PD resultant force, moment, bi-moment, and bi-shear states with their classical counterparts is established using the constitutive correspondence method. Numerical implementation strategy is furnished for both quasi-static and dynamic cases. The solution for quasi-static load is obtained through the Newton-Raphson method. The proposed model is validated against finite element solutions considering cantilever beam and lattice structures. Quasi-static deformation responses of 3×3×3 octet and single unit compression-torsion lattice structures are presented further to demonstrate the effectiveness of proposed beam model. A new bond breaking criterion is proposed based on critical stretch, critical relative rotation, and critical relative warping amplitude and failure of the compression-torsion lattice structures under compressive load is simulated. The Newmark-beta method is utilized to solve the governing equations for dynamic loading. Numerical simulations include dynamic analysis of octet and compression-torsion lattice structures.本文提出了一种基于Simo-Reissner理论的近场动力学(PD)框架有限变形梁模型,用于处理由扭转引起的弯曲变形。在每个材料点处考虑了三个平移、三个旋转和一个弯曲幅度的七个自由度。通过采用线性和角动量全球平衡以及Simo关于变形场的假设,获得了梁的控制方程。利用本构对应方法建立了PD结果力、矩、二矩和二剪状态与它们的经典对应物之间的联系。为静力和动力情况提供了数值实现策略。通过牛顿-拉夫森方法获得了静力载荷的解。将该模型与考虑悬臂梁和网格结构的有限元解进行了验证。进一步展示了3×3×3八面体和单单元压缩-扭转网格结构的静力变形响应,以示例该梁模型的有效性。提出了一种基于临界伸长、临界相对转动和临界相对弯曲振幅的新的断裂准则,并通过Newmark-beta方法模拟了压缩载荷下压缩-扭转网格结构的失效。数值模拟包括八面体和压缩-扭转网格结构的动态分析。A novel machine learning framework for impact force prediction of foam-filled multi-layer lattice composite structuresJiye Chen, Yufeng Zhao, Hai Fang, Zhixiong Zhang, Zheheng Chen, Wangwang Hedoi:10.1016/j.tws.2024.112607一种用于泡沫填充多层晶格复合材料结构冲击力预测的机器学习框架Numerical simulations can provide valuable insights for the optimization of design and operational management; however, they are often impractical and computationally intensive. Machine learning methods are appealing to these problems due to their sufficient efficiency and accuracy. In this study, a novel framework for predicting the impact responses of foam-filled multi-layer lattice composite structures (FMLCSs) was proposed by combining the accurate finite element (FE) analyses, surrogate models, fast Fourier transform (FFT) method, and inverse FFT (IFFT) method. Firstly, reliable FM models were established to simulate the crashworthiness of the five FMLCSs under impact loading, including an analysis of energy transformation. Subsequently, surrogate models, namely radial basis function (RBF), polynomial response surface (PRS), Kriging (KRG), and back propagation neural network (BPNN), combined with methods of FFT and IFFT, were employed to predict the impact force-time series of the FMLCSs. More than 1000 frequency points were employed for each type of FMLCS, and all the R-square (R2) values of the established surrogate models exceeded 0.95, indicating that the proposed framework accurately predicted the impact duration and impact responses in the frequency domain. In addition, parameter sensitivity analysis revealed that a high peak impact force was accompanied by a short impact duration. Moreover, increasing the lattice-web height resulted in a significant increase in the impact duration.数值模拟可以为优化设计和运营管理提供有价值的见解;然而,它们通常是不切实际的,并且需要大量的计算。机器学习方法因其足够的效率和准确性而吸引着这些问题。本研究结合精确有限元(FE)分析、代理模型、快速傅立叶变换(FFT)方法和逆傅立叶变换(IFFT)方法,提出了一种预测泡沫填充多层晶格复合材料结构(FMLCSs)冲击响应的新框架。首先,建立了可靠的FM模型,模拟了5种fmlcs在冲击载荷下的耐撞性,并对能量转换进行了分析。随后,采用径向基函数(RBF)、多项式响应面(PRS)、Kriging (KRG)和反向传播神经网络(BPNN)等替代模型,结合FFT和IFFT方法对fmlcs的冲击力-时间序列进行预测。每种类型的FMLCS都使用了1000多个频率点,所有的R平方(R2)所建立的代理模型值均超过0.95,表明所提出的框架在频域上准确预测了冲击持续时间和冲击响应。此外,参数敏感性分析表明,峰值冲击力高,冲击持续时间短。此外,格腹板高度的增加导致冲击持续时间的显著增加。4D printed bio-inspired polygonal metamaterials with tunable mechanical propertiesXueli Zhou, Hongpei Liu, Jifeng Zhang, Lei Ren, Lu Zhang, Qingping Liu, Bingqian Li, Chao Xu, Luquan Rendoi:10.1016/j.tws.2024.112609具有可调机械性能的4D打印仿生多边形超材料Conventional vibration isolators are designed and assembled so that their structure and vibration isolation performance cannot be adjusted and have a single function when facing complex working conditions. Inspired by a cat's adaptive adjustment of its limb structure to land safely when leaping from a height, we designed a bio-inspired polygonal metamaterial and 3D-molded it based on 4D printing of shape memory polymers (SMP). Based on the shape memory effect of the SMP, the BPM can obtain arbitrary temporary shapes under the combined effect of temperature and force. According to the analysis of the energy absorption test, by change the compressive strain of the BPM temporary shape, it is possible to adjust the shape of the single-cell structure while decreasing its specific energy absorption by up to 80%. The locally controllable compressive deformation and programmable mechanical properties of the BPM structure are achieved through rational structural parameter design. In addition, thermally tunable vibration-absorbing behavior is achieved by combining the tunable stiffness properties of the printed material. This study provides new possibilities for intelligent tuning of cushion vibration isolators under complex and variable operating conditions.常规隔振器的结构和隔振性能在复杂工况下无法调整,功能单一。受猫在从高处跳跃时对肢体结构进行适应性调整以安全着陆的启发,我们设计了一种仿生多边形超材料,并基于形状记忆聚合物(SMP)的4D打印对其进行了3d成型。基于SMP的形状记忆效应,BPM可以在温度和力的共同作用下获得任意的临时形状。根据能量吸收试验分析,通过改变BPM临时形状的压缩应变,可以在调整单细胞结构形状的同时,将其比能量吸收降低高达80%。通过合理的结构参数设计,实现了BPM结构压缩变形局部可控和力学性能可编程。此外,通过结合印刷材料的可调刚度特性,实现了热可调的吸振性能。该研究为复杂多变工况下缓冲隔振器的智能调谐提供了新的可能性。A novel concurrent multiscale method based on the coupling of Direct FE2 and CPFEMYehui Cui, Zhilang Zhangdoi:10.1016/j.tws.2024.112610 一种基于直接FE2和CPFEM耦合的并行多尺度方法Performing concurrent simulations of macroscopic behaviors and microscopic structures using the crystal plasticity finite element method (CPFEM) presents a substantial difficulty with existing numerical techniques. To address this issue, a novel multi-scale method is proposed that couples CPFEM with a multiscale FEM, specifically Direct FE2. This facilitates the implementation of Direct CP-FE2 in this work. The micro representative volume elements (RVEs) equipped with a crystal plasticity constitutive model and the macro mesh are integrated into a monolithic solution scheme within the Direct FE2 framework. The proposed method integrates the multiscale simulation capability of Direct FE2 with the crystal plasticity model of CPFEM. Alpha titanium (α-Ti), which exhibits two distinct plastic mechanisms of slip and twinning, is chosen as the subject of investigation for conducting numerical experiments. The accuracy and efficiency of the Direct CP-FE2 model are evaluated through multiple plate tension and beam bending tests. The effective validation against the FEM model demonstrated the capability of Direct CP-FE2 to forecast macroscopic deformation behaviors. Meanwhile, the Direct CP-FE2 model can reveal the activation of slip/twinning systems and the evolution of crystal texture at a microscopic level. The influence of the grain orientation-dependent effect can be well considered into the macroscopic analysis with the help of Direct CP-FE2. Based on the testing examples, we demonstrate that the yield state of the macrostructure is enhanced when the crystal orientation is closer to the (0001) direction. Consequently, there exist very little crystal rotation behavior, hindering the evolution of the crystal texture.利用晶体塑性有限元方法(CPFEM)进行宏观行为和微观结构的并行模拟是现有数值技术的一大难点。为了解决这一问题,提出了一种新的多尺度方法,即耦合CPFEM和多尺度FEM,特别是直接有限元法。这有助于在本工作中实现Direct CP-FE2。在Direct FE2框架内,将具有晶体塑性本构模型的微代表体积元(RVEs)与宏观网格集成为整体求解方案。该方法将Direct FE2的多尺度模拟能力与CPFEM的晶体塑性模型相结合。选择具有滑移和孪晶两种不同塑性机制的α钛(α-Ti)作为研究对象进行数值实验。通过多次板拉伸和梁弯曲试验,对Direct CP-FE2模型的精度和效率进行了评价。通过对有限元模型的有效验证,证明了Direct CP-FE2预测宏观变形行为的能力。同时,Direct CP-FE2模型可以在微观水平上揭示滑移/孪晶系统的激活和晶体织构的演变。在Direct CP-FE2的帮助下,可以很好地考虑晶粒取向依赖效应的影响。实验结果表明,晶体取向越接近(0001)方向,宏观结构的屈服态越强。因此,晶体旋转行为很少,阻碍了晶体织构的演变。来源:复合材料力学仿真Composites FEM

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