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【新文速递】2023年12月22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 1 篇,International Journal of Plasticity 1 篇,Thin-Walled Structures 7 篇

International Journal of Solids and Structures

A model-based simulation framework for coupled acoustics, elastodynamics, and damage with application to nano-pulse lithotripsy

Yangyuanchen Liu, Pei Zhong, Oscar Lopez-Pamies, John E. Dolbow

doi:10.1016/j.ijsolstr.2023.112626

基于模型的声学、弹性力学和损伤耦合模拟框架,应用于纳米脉冲碎石术

We develop a model for solid objects surrounded by a fluid that accounts for the possibility of acoustic pressures giving rise to damage on the surface of the solid. The propagation of an acoustic pressure in the fluid domain is modeled by the acoustic wave equation. On the other hand, the response of the solid is described by linear elastodynamics coupled with a gradient damage model, one that is based on a cohesive-type phase-field description of fracture. The interaction between the acoustic pressure and the deformation and damage of the solid are represented by transmission conditions at the fluid-solid interface. The resulting governing equations are discretized using a finite-element/finite-difference method that pays particular attention to the spatial and temporal scales that need to be resolved. Results from model-based simulations are provided for a benchmark problem as well as for recent experiments in nano-pulse lithotripsy. A parametric study is performed to illustrate how damage develops in response to the driving force (magnitude and location of the acoustic source) as a function of the fracture resistance of the solid. The results are shown to be qualitatively consistent with experimental observations for the location and size of the damage fields on the solid surface. A study of limiting cases also suggests that both the threshold for damage and the critical fracture energy are important to consider in order to capture the transition from damage initiation to complete localization. A low-cycle fatigue model is proposed that degrades the fracture resistance of the solid as a function of accumulated tensile strain energy, and it is shown to be capable of capturing damage localization in simulations of multi-pulse nano-pulse lithotripsy.

我们为被流体包围的固体物体建立了一个模型,该模型考虑了声压对固体表面造成破坏的可能性。声压在流体域中的传播由声波方程建模。另一方面,固体的响应则由线性弹性动力学和梯度损伤模型(基于断裂的内聚型相场描述)来描述。声压与固体变形和损伤之间的相互作用由流体-固体界面上的传输条件表示。使用有限元/有限差分法对所得到的控制方程进行离散化,该方法特别关注需要解决的空间和时间尺度问题。基于模型的模拟结果适用于基准问题以及最近的纳米脉冲碎石实验。进行了一项参数研究,以说明损伤是如何随着驱动力(声源的大小和位置)的变化而发展的,是固体断裂阻力的函数。研究结果表明,固体表面损伤场的位置和大小与实验观察结果在性质上是一致的。对极限情况的研究还表明,为了捕捉从损伤开始到完全局部化的过渡,损伤阈值和临界断裂能量都是需要考虑的重要因素。我们提出了一个低循环疲劳模型,该模型可使固体的抗断裂性能退化为累积拉伸应变能的函数,并证明它能够在多脉冲纳米脉冲碎石模拟中捕捉损伤局部化。


Mechanics of Materials

Identification of thermo-viscoplastic behavior for AA6061 under in-plane biaxial loadings

J. Liang, D. Guines, L. Leotoing

doi:10.1016/j.mechmat.2023.104898

确定 AA6061 在平面双轴载荷作用下的热粘塑性行为

This work aims to investigate the thermo-visco-plastic behavior of an aluminum alloy (AA6061) sheet metal submitted to in-plane biaxial loadings under warm conditions. Biaxial tensile tests are performed in a temperature range from room temperature to 160 °C, and in a strain rate range from quasi-static to the so-called “intermediate” strain rate (up to few s−1). The specimen shape used in this study has been previously defined and validated by the authors to identify the viscoplastic hardening models of metallic alloys at large strains. A specific device leading to a uniform temperature in the sample is associated with a dynamic biaxial traction bench to carry out the temperature and strain rate dependent characterizations. From these experiments, both the experimental forces measured on each axis of the in-plane biaxial specimen and the principal strains at the center of the specimen are obtained. These experimental data are then used in an inverse analysis loop, based on a finite element model of the biaxial test, to calibrate the parameters of a thermo-viscoplastic strain hardening model by minimizing the difference between the experimental and numerical principal strains at the center point of the specimen. Finally, it is shown that the identified hardening model well predicts the flow stress of AA6061 under different temperatures and strain rates for a strain level of up to 40%.

这项工作旨在研究铝合金(AA6061)板材在温暖条件下承受平面双轴载荷的热粘塑性行为。双轴拉伸试验的温度范围从室温到 160 °C,应变速率范围从准静态到所谓的 "中间 "应变速率(高达几 s-1)。本研究中使用的试样形状由作者先前定义并验证,用于确定金属合金在大应变下的粘塑性硬化模型。一个能使试样温度均匀的特定装置与一个动态双轴牵引台相连接,以进行温度和应变速率相关特性分析。通过这些实验,可以获得在平面双轴试样的每个轴上测量到的实验力和试样中心的主应变。然后,基于双轴测试的有限元模型,将这些实验数据用于反分析循环,通过最小化试样中心点的实验主应变和数值主应变之间的差异,校准热粘塑性应变硬化模型的参数。结果表明,所确定的硬化模型可以很好地预测 AA6061 在不同温度和应变率下的流动应力,应变水平最高可达 40%。


International Journal of Plasticity

A coupled phase-field and crystal plasticity model for understanding shock-induced phase transition of iron

Songlin Yao, Jidong Yu, Xiaoyang Pei, Yinan Cui, Hao Zhang, Hui Peng, Yi Li, Qiang Wu

doi:10.1016/j.ijplas.2023.103860

用于理解冲击诱导铁相变的耦合相场和晶体塑性模型

In the current work, we propose a chemical-potential-based phase-field model coupled with dynamic crystal plasticity based on a unified energy framework with the aim of understanding the shock-induced α–ϵ–α phase transition (PT) of iron. The plasticity is coupled with the PT through controlling the shear strain energy and the entropy rise during the dynamic deformation. In contrast with previous models, the PT pressure in this model is not a constant but obeys the Gaussian distribution with the applied stress, which is in accordance with the hysteresis effect observed in quasi-static experiments. Moreover, the contribution of multivariants to PT can be distinguished based on reaction-pathway theory. The proposed model quantitatively reproduces the split of the three-wave structure and the “loop” features of the plasticity wave and the phase transition wave, which agree well with the shock loading experiments of polycrystalline and monocrystalline iron, and cannot be well captured by previous models. Furthermore, many new insights in shock wave physics are gained. PT kinetics is found to be influenced by plasticity via the hysteresis effect and the newly generated stress wave induced by the dynamic deformation. First, the rarefaction wave induced by plastic deformation, as well as that by the growth of the child phase, behind the shock front reduces the PT plateau in the wave profile. Second, the plasticity controls the PT driving force and influences the PT hysteresis effect behind the shock front. As yield stress increases, less strain energy is plastically dissipated, and more strain energy drives the PT behind the shock front more efficiently, which results in a sharper slope of the P2 wave.

在本工作中,我们基于统一的能量框架,提出了一种基于化学势的相场模型,该模型与动态晶体塑性相耦合,旨在理解冲击诱导的铁α-ϵ-α相变(PT)。塑性通过控制动态变形过程中的剪切应变能和熵升与 PT 相耦合。与以前的模型不同,该模型中的 PT 压力不是一个常数,而是随外加应力服从高斯分布,这与准静态实验中观察到的滞后效应相一致。此外,基于反应途径理论,可以区分多变量对 PT 的贡献。所提出的模型定量地再现了三波结构的分裂以及塑性波和相变波的 "循环 "特征,这与多晶铁和单晶铁的冲击加载实验十分吻合,是以往模型所不能很好捕捉的。此外,还获得了许多有关冲击波物理学的新见解。研究发现,PT 动力学受到塑性的影响,塑性通过滞后效应和动态变形引起的新产生的应力波产生影响。首先,塑性变形引起的稀释波和子相增长引起的稀释波在冲击波前沿后方减少了波剖面中的 PT 高原。其次,塑性控制 PT 驱动力,并影响冲击前沿后的 PT 滞后效应。随着屈服应力的增加,塑性耗散的应变能减少,更多的应变能更有效地驱动冲击前沿后的 PT,从而导致 P2 波的斜率变大。


Thin-Walled Structures

Investigation on damage behavior of composite T-shaped stiffened panels under compression after multi-point impact considering impact positions

Zhengwei Meng, Linhai Huang, Pengfei Wang, Wei Zhang, Jin Sun, Ming Zhao, Zhaoxin Yun, Xiaoling Ai, Nianhong Li

doi:10.1016/j.tws.2023.111514

考虑撞击位置的多点撞击后复合 T 型加劲板受压破坏行为研究

Considering the randomness and non-uniqueness of the impact damage distribution of composite structures, both experimental and numerical simulation methods are employed to systematically explore the multi-point impact damage and compression-after-impact damage behavior of composite T-shaped stiffened panels under three types of impact positions. Non-destructive testing, and numerical simulation methods are used to examine the morphology of multi-point impact damage. The compression failure process of the impacted specimens and the intact specimens (reference group) is investigated by the electrometric method. In addition, the impact failure mechanism and compression failure mechanism is further studied by combining with the numerical simulation method. The results demonstrate that impact position B (the edge of each stiffener flange), the type of impact damage is more complex, in addition to fiber/matrix damage, it contains skin/stiffener debonding damage/layer fracture damage. Especially layer fracture damage, which significantly affects the compression damage behavior of structures.

考虑到复合材料结构冲击损伤分布的随机性和非唯一性,采用实验和数值模拟两种方法系统地探讨了复合材料 T 型加劲板在三种冲击位置下的多点冲击损伤和冲击后压缩损伤行为。采用无损检测和数值模拟方法研究了多点冲击损伤的形态。采用电测法研究了受冲击试样和完好试样(参照组)的压缩破坏过程。此外,还结合数值模拟方法进一步研究了冲击破坏机理和压缩破坏机理。结果表明,冲击位置 B(各加劲件翼缘边缘)的冲击破坏类型较为复杂,除纤维/基体破坏外,还包含表皮/加劲件脱粘破坏/层断裂破坏。尤其是层状断裂损伤,会对结构的压缩损伤行为产生重大影响。


A fast Chebyshev spectral approach for vibroacoustic behavior analysis of heavy fluid-loaded baffled rectangular plates with general boundary conditions

Tiantong Zhao, Tiangui Ye, Yuehua Chen, Guoyong Jin, Yukun Chen, Zhigang Liu

doi:10.1016/j.tws.2023.111518

用于分析具有一般边界条件的重流体载荷障板振动声学行为的快速切比雪夫频谱方法

A computationally efficient Chebyshev spectral approach is proposed to solve the vibroacoustic response of heavy fluid-loaded baffled rectangular plates. The governing equations for the displacements of motion in rectangular plates and the sound pressure in the Helmholtz integral are formulated using high-order, first-class Chebyshev polynomial expansions. This formulation is combined with Gauss-Chebyshev-Lobatto sampling. The quadruple integral encountered in solving the work done by the heavy fluid on the plate is reformulated into the configuration of a tensor product. The approach significantly reduces the computation time for solving the acoustic equations, bringing the vibration response of fluid-loaded plates closer to that of vacuum plates and limiting it to just a few seconds. The elastic boundary conditions of the rectangular plates are simulated using linear and rotational springs. Predictions of vibroacoustic behavior, including plate velocity, sound pressure, sound power, and radiation efficiency, are validated against literature results. The accuracy and efficiency of the Chebyshev spectral approach for the vibroacoustic coupling systems are demonstrated by the presence of exemplary agreements. Furthermore, this study investigates the effect of boundary conditions, geometric characteristics, and damping variables on the vibroacoustic behavior of rectangular plates.

本文提出了一种计算高效的切比雪夫频谱方法,用于求解重型流体负载障板矩形板的振动声学响应。矩形板运动位移和亥姆霍兹积分声压的控制方程采用高阶、一流的切比雪夫多项式展开来计算。该公式与高斯-切比雪夫-洛巴图采样相结合。在求解重流体对板做功时遇到的四重积分被重新表述为张量乘积的配置。这种方法大大减少了求解声学方程的计算时间,使流体负载板的振动响应更接近真空板的振动响应,并将其限制在几秒钟内。利用线性弹簧和旋转弹簧模拟了矩形板的弹性边界条件。振动声学行为的预测,包括板速度、声压、声功率和辐射效率,都与文献结果进行了验证。切比雪夫频谱方法在振声耦合系统中的准确性和效率通过示范协议的存在得到了证明。此外,本研究还探讨了边界条件、几何特征和阻尼变量对矩形板振动声学行为的影响。


Finite element dynamic modeling and vibration reduction analysis of the double-lap bolted thin plate with partially attached constrained layer damping

Rongfei Zhang, Wei Sun, Haitao Luo, Hongwei Ma, Hui Zhang

doi:10.1016/j.tws.2023.111522

带部分附着约束层阻尼的双搭接螺栓薄板的有限元动态建模和减振分析

The double-lap bolted thin plate is widely used, but it is easy to produce vibration. In this paper, the method of attaching H-shaped constrained layer damping (CLD) is adopted to reduce vibration, and the finite element dynamic model of the double-lap bolted thin plate with H-shaped CLD is investigated. The innovations of the modeling method are described as follows. A composite element with four nodes and 28 degrees of freedom (DOFs) is produced by taking into account the interlaminar shear deformation of the CLD structure and employing complex modulus to quantify the damping characteristics of the viscoelastic layer. A series of transition elements are constructed to conduct the assembly of elements with inconsistent dimensions. Complex stiffness spring components and mass elements are presented to simulate the stiffness, damping, and mass characteristics of the double-lap bolt joint based on the crock-shaped stress distribution in the double-lap bolt joint and taking the bolt effect region into account. Finally, a case study is carried out, and the rationality of the finite element model of the bolted structure in solving the natural characteristics and vibration response parameters is verified by the established experimental tests. At the same time, the test and modeling results show that the H-shaped CLD reduces vibration on the double-lap bolted thin plate. Furthermore, based on the established finite element model, the influence of the attaching position of the H-shaped CLD, thicknesses of the viscoelastic layer, and the constraining layer on the vibration characteristics of the bolted structure are analyzed.

双搭接螺栓薄板应用广泛,但容易产生振动。本文采用附加 H 型约束层阻尼(CLD)的方法来减少振动,并研究了附加 H 型约束层阻尼的双搭接螺栓薄板的有限元动态模型。建模方法的创新点如下。考虑到 CLD 结构的层间剪切变形,并采用复模量量化粘弹性层的阻尼特性,生成了一个具有四个节点和 28 个自由度 (DOF) 的复合元素。我们构建了一系列过渡元件,用于组装尺寸不一致的元件。提出了复杂的刚度弹簧元件和质量元件,以模拟双圈螺栓连接处的刚度、阻尼和质量特性,其依据是双圈螺栓连接处的钩形应力分布,并考虑了螺栓效应区域。最后,进行了案例研究,并通过已建立的试验验证了螺栓结构有限元模型在求解自然特性和振动响应参数方面的合理性。同时,试验和建模结果表明,H 型 CLD 可减少双搭接螺栓薄板的振动。此外,基于已建立的有限元模型,分析了 H 型 CLD 连接位置、粘弹性层和约束层厚度对螺栓结构振动特性的影响。


Axial and radial reversibility and energy absorption behaviors of braided shape memory composite thin-walled tubes

Qin Yang, Renyi Liu, Zhiyong Li, Bohong Gu, Baozhong Sun, Wei Zhang

doi:10.1016/j.tws.2023.111524

编织形状记忆复合材料薄壁管的轴向和径向可逆性及能量吸收行为

Braided shape memory polymer composites (SMPCs), which integrate braided structures with shape memory polymers, are well-known for their superior mechanical properties, reversible deformation, and recovery capabilities. This study focused on exploring the reusable energy absorption capacity of intelligent braided SMPC tubes. The effects of braiding structure on compression modes, mechanical properties, energy absorption, shape memory performance, and repeatability under axial and radial compression have been comprehensively investigated. The results show that SMPC tubes have a shape recovery ratio exceeding 94% after four cycles. As the number of compressions increased, both the mechanical and energy absorption properties decreased, particularly during the first compression. Higher energy absorption capacity has been observed in SMPC tubes with larger braiding angles, up to 32.51 J, 2.3 times that of pure TPU tubes. These findings offer potential approaches for the development of high-performance reusable protective devices and lightweight intelligent structures.

编织形状记忆聚合物复合材料(SMPC)是编织结构与形状记忆聚合物的集成,以其优异的机械性能、可逆变形和恢复能力而闻名。本研究的重点是探索智能编织 SMPC 管的可重复使用能量吸收能力。全面研究了编织结构对轴向和径向压缩下的压缩模式、机械性能、能量吸收、形状记忆性能和重复性的影响。结果表明,SMPC 管在四个循环后的形状恢复率超过 94%。随着压缩次数的增加,机械性能和能量吸收性能都有所下降,尤其是在第一次压缩时。在具有较大编织角的 SMPC 管中观察到了更高的能量吸收能力,高达 32.51 J,是纯 TPU 管的 2.3 倍。这些发现为开发高性能可重复使用的保护装置和轻质智能结构提供了潜在的方法。


Investigation of nonlinear magnetic stiffness based thin-layer Stacked piezoelectric generators with a force-amplification structure

Min Wang, Jiepeng Liu, Yan Peng, Zhongjie Li

doi:10.1016/j.tws.2023.111525

基于具有力放大结构的薄层叠层压电发生器的非线性磁刚度研究

This paper investigates a nonlinear piezoelectric stack energy harvester incorporating a magnetic spring (NPEH) that utilizes impact-induced frequency modulation to augment the harvested power. The proposed configuration comprises a force amplifier, a piezoelectric stack, a spring-mass system, and a limiter. We formulate a two-degree-of-freedom (2DoF) theoretical model that accounts for the nonlinear characteristics of the system and corroborate it with experimental data. We examine the effects of system parameters on the output performance of the NPEH and demonstrate that the nonlinear magnetic spring facilitates a wideband energy harvesting. For instance, when the surface magnetic field intensities of the upper and lower magnets are 156mT and 256mT, respectively, the operational bandwidth reaches 5.23Hz, which is 154% greater than that of a linear spring system. Additionally, the nonlinear magnetic spring mitigates the voltage decay during the collision period due to its hysteresis response, thereby increasing the average power. At an excitation frequency of 9 Hz and with surface field strengths of the upper and lower magnets set at 156mT and 256mT respectively, the NPEH generates an RMS power of 2.2mW (with an instantaneous power peak of 1.20W). We provide design guidelines for optimizing the energy harvesting performance based on the parametric analysis.

本文研究了一种包含磁性弹簧(NPEH)的非线性压电堆能量收集器,它利用冲击引起的频率调制来增强收集的功率。所提出的配置包括一个力放大器、一个压电叠层、一个弹簧-质量系统和一个限制器。我们制定了一个两自由度(2DoF)理论模型,该模型考虑了系统的非线性特性,并与实验数据相互印证。我们研究了系统参数对 NPEH 输出性能的影响,并证明非线性磁弹簧有助于宽带能量采集。例如,当上下磁体的表面磁场强度分别为 156mT 和 256mT 时,工作带宽达到 5.23Hz,比线性弹簧系统高出 154%。此外,非线性磁性弹簧由于其滞后响应,可减轻碰撞期间的电压衰减,从而提高平均功率。在激励频率为 9 Hz,上下磁体的表面磁场强度分别为 156mT 和 256mT 时,NPEH 产生的有效功率为 2.2mW(瞬时功率峰值为 1.20W)。我们根据参数分析提供了优化能量收集性能的设计指南。


Theoretical Model of Energy Absorption for Square Tubes under Transverse Loading with Variable Axial Constraint Condition

Junyuan Zhang, Jian Xie, Danfeng Zheng, Chang Su, Hao Zhou

doi:10.1016/j.tws.2023.111526

轴向约束条件可变的横向载荷下方形管的能量吸收理论模型

Thin-walled tubes in the actual engineering structure (e.g., autobody) are usually connected to other structure, and the boundary constraint condition at both ends of tubes are usually very complex when bending deformation occurs under transverse loading. This paper aims at the effect and mechanism of axial constraint on the bending energy absorption effect of thin-walled tube under limited and variable axial constraint condition at both ends. A typical of thin-walled tube, square tube, is taken as an example. Firstly, we compare the experiment results of square tube under transverse loading with three-point-bending condition and fully clamped condition, revealing that the axial constraint force has a significant effect on the energy absorption effect. After that, a FE model of the square tube under variable axial constraint condition at both ends is established and validated based on experiment. Based on the validated FE model, the effect of different sizes of axial constraint stiffness on the bending energy absorption of square tube are investigated, and it is found that it has a significant effect on the deformation mode and bending energy absorption. With the increase of axial constraint stiffness, it will mainly affect the latter segment of the force-displacement curve in the bending process, which increases the bending energy absorption. Finally, theoretical models are developed to predict the force-displacement curves and bending energy absorption of the square tube under three different types of variable axial constraint properties: linear axial constraint, unequal linear axial constraint and nonlinear axial constraint.

实际工程结构(如车身)中的薄壁管通常与其他结构相连,在横向载荷作用下发生弯曲变形时,管两端的边界约束条件通常非常复杂。本文旨在研究在两端有限和可变轴向约束条件下,轴向约束对薄壁管弯曲能量吸收效应的影响和机理。本文以典型的薄壁方管为例。首先,我们比较了方管在三点弯曲条件和全夹紧条件下横向加载的实验结果,发现轴向约束力对能量吸收效果有显著影响。随后,根据实验结果建立并验证了两端可变轴向约束条件下方管的有限元模型。根据验证后的 FE 模型,研究了不同大小的轴向约束刚度对方管弯曲能量吸收的影响,结果发现轴向约束刚度对变形模式和弯曲能量吸收有显著影响。随着轴向约束刚度的增大,主要会影响弯曲过程中力-位移曲线的后一段,从而增加弯曲能量吸收。最后,建立了理论模型来预测方管在三种不同类型的可变轴向约束特性(线性轴向约束、不等线性轴向约束和非线性轴向约束)下的力-位移曲线和弯曲能量吸收。


Experimental investigation of liquid-tank interaction effects on full containment LNG storage tanks through shaking table tests

Wei Liu, Chang Xiao, Hao Zhou, Chenyan Wang

doi:10.1016/j.tws.2023.111527

通过振动台试验研究液罐相互作用对全密封液化天然气储罐的影响

Liquefied natural gas (LNG) storage tanks play a crucial role as primary storage facilities in modern gas supply systems. This study investigates the seismic response of full containment LNG storage tanks through shaking table tests. A 1/14 scale model structure is meticulously constructed and subjected to testing. The test comprises two distinct phases: an empty tank phase and a water-filled tank phase. The primary emphasis of this paper is the exploration of the effects of liquid–tank interaction. A novel no-contact binocular video synchronization measurement system is developed by utilizing high-speed cameras to accurately measure the liquid sloshing height. The seismic responses of both the liquid and the tank, including acceleration and hydrodynamic pressure, are meticulously measured and analyzed. Findings reveal that the filling fluid has a significant effect on the tank, particularly the steel inner tank. The liquid sloshing phenomenon influences the hydrodynamic pressures, with the magnitude of influence decreasing as the liquid depth increases. In addition, a comparison is conducted between the experimental liquid sloshing height and hydrodynamic pressure results and those obtained from liquid linear forced sloshing theory. Liquid linear forced sloshing theory fails to accurately predict liquid sloshing height for large-amplitude sloshing but provides a rough estimate of hydrodynamic pressure distribution on the tank wall. Two simplified mechanical models for liquid sloshing are proposed and compared with the experimental results. The outcomes demonstrate that the Housner method exhibits relatively large errors, while the simplified mechanical models based on liquid linear forced sloshing theory accurately describe cases with small-amplitude liquid sloshing.

液化天然气(LNG)储罐是现代天然气供应系统中的主要储存设施,起着至关重要的作用。本研究通过振动台试验研究了全封闭液化天然气储罐的地震响应。我们精心建造了一个 1/14 比例的模型结构,并对其进行了测试。测试包括两个不同的阶段:空罐阶段和充水阶段。本文的主要重点是探索液体与储罐相互作用的影响。通过利用高速摄像机精确测量液体荡动高度,开发了一种新型非接触式双目视频同步测量系统。对液体和罐体的地震响应,包括加速度和流体动力压力,进行了细致的测量和分析。研究结果表明,填充液体对罐体,尤其是钢制内罐有很大影响。液体滑动现象会影响流体动力压力,影响程度随着液体深度的增加而减小。此外,还对实验得出的液体荡高和水动力压力结果与液体线性强制荡高理论得出的结果进行了比较。液体线性强制滑动理论无法准确预测大振幅滑动时的液体滑动高度,但可以粗略估计罐壁上的水动力压力分布。本文提出了两种简化的液体荡动力学模型,并与实验结果进行了比较。结果表明,Housner 方法的误差相对较大,而基于液体线性强制滑动理论的简化机械模型则能准确描述小振幅液体滑动的情况。



来源:复合材料力学仿真Composites FEM
ACTMechanicalSystemMAGNETDeform振动疲劳断裂复合材料碰撞非线性理论化机材料螺栓
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【新文速递】2023年12月25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 2 篇,Composites Part B: Engineering 2 篇,Composites Science and Technology 1 篇Composite StructuresDesign of multi-material structures using material jetting technology: Topology optimisation, numerical analysis and experimentsMarco Montemurro, Gianluca Alaimo, Enrico Panettieri, Anita Catapano, Massimo Carraturo, Ferdinando Auricchiodoi:10.1016/j.compstruct.2023.117838利用材料喷射技术设计多材料结构:拓扑优化、数值分析和实验This paper presents a thorough experimental/numerical validation of optimised multi-material structures fabricated by material jetting technology. The proposed methodology uses, on the one hand, non-uniform rational basis spline (NURBS) entities to represent the geometric descriptor associated with each material phase constituting the continuum and, on the other hand, a general multi-phase material interpolation scheme to penalise the stiffness tensor of the structure. Two design requirements are included in the problem formulation: the lightness and the minimum length scale of each material phase. The influence of the integer parameters intervening in the definition of the NURBS entity and the influence of different combinations of material phases on the optimised solutions are investigated. The proposed approach is applied to 2D and 3D benchmark structures subjected to prescribed displacements representative of a three-point bending test. Based on the result of the topology optimisation process one of the optimised solutions, balancing the requirements of structural stiffness, lightness, and manufacturing constraints, is selected, manufactured and tested. A comparison between experimental and numerical results (obtained by non-linear analyses) is carried out to show the effectiveness of the approach.本文对利用材料喷射技术制造的优化多材料结构进行了全面的实验/数值验证。所提出的方法一方面使用非均匀有理基础样条曲线(NURBS)实体来表示与构成连续体的各材料相相关的几何描述符,另一方面使用一般多相材料插值方案来对结构的刚度张量进行惩罚。问题表述中包含两个设计要求:每个材料相的轻度和最小长度尺度。研究了 NURBS 实体定义中的整数参数的影响,以及不同材料相组合对优化解决方案的影响。所提出的方法适用于二维和三维基准结构,这些结构受到代表三点弯曲测试的规定位移的影响。根据拓扑优化过程的结果,在平衡结构刚度、轻度和制造限制等要求的基础上,选择、制造并测试了其中一个优化方案。对实验结果和数值结果(通过非线性分析获得)进行比较,以显示该方法的有效性。All-Scale Approach to Evaluate the Elasticity and Strength of Carbon-Allotrope Reinforced PolyimideDiogo Galhofo, António P. C. Duarte, Nuno Silvestredoi:10.1016/j.compstruct.2023.117841评估碳同位素增强聚酰亚胺弹性和强度的全尺度方法This computational study conducts a comprehensive all-scale analysis to predict the mechanical behavior (elasticity and strength) of polyimide matrices (Kapton@) reinforced with carbon nanostructures, spanning nanoscale, microscale, mesoscale, and macroscale. Representative volume elements at each scale undergo tensile and shear loadings to extract mechanical properties. Homogenization techniques are applied to transition between scales, considering these properties. Two nanostructures (graphene and γ-graphyne) are explored as reinforcements, evaluating the influence of volume fraction and orientation on composite mechanical properties. Results are validated through comparison with theoretical, computational, and experimental studies. Composite materials exhibited significant improvements in stiffness (up to 44% at a volume fraction of 0.5%) and tensile strength (up to 25% at a volume fraction of 0.5%) compared to the pristine polymeric matrix.这项计算研究进行了全面的全尺度分析,以预测用碳纳米结构增强的聚酰亚胺基质(Kapton@)的机械行为(弹性和强度),分析范围包括纳米尺度、微尺度、中尺度和宏观尺度。对每个尺度上的代表性体积元素进行拉伸和剪切加载,以提取机械性能。考虑到这些特性,均质化技术被应用于尺度之间的过渡。将两种纳米结构(石墨烯和γ-石墨烯)作为增强材料进行研究,评估体积分数和取向对复合材料机械性能的影响。通过与理论、计算和实验研究的比较,对结果进行了验证。与原始聚合物基体相比,复合材料在刚度(体积分数为 0.5%时可提高 44%)和拉伸强度(体积分数为 0.5%时可提高 25%)方面都有明显改善。Probabilistic fatigue strength assessment of cross-ply laminates: Exploring effects of manufacturing defects through a two-scale modeling approachSara Eliasson, Gustav Hultgren, Zuheir Barsoum, Per Wennhagedoi:10.1016/j.compstruct.2023.117844交叉层压板的概率疲劳强度评估:通过双尺度建模方法探索制造缺陷的影响The study presents a two-scale modeling approach allowing for an efficient fatigue strength evaluation on a macro scale considering a micro-mechanical defect characterization of a Carbon Fiber Reinforced Polymer (CFRP) material. The modeling approach integrates a macro model with the effective elastic properties from micro-mechanical simulations considering voids. This enables the analysis of defects’ influence on material fatigue strength using a probabilistic weakest link approach. A CFRP laminate with a cross-ply layup was investigated. Two simulation case studies demonstrate the effect of void content and size on the characteristic fatigue strength. An experimental investigation was conducted testing the laminates in tension-tension fatigue verifying the predicted numerical behavior. The numerical models identify a difference in the characteristic fatigue strength consistent with the fatigue test results. It is numerically concluded that the investigated CFRP material’s fatigue strength is affected by the presence of voids and even with only a slight difference in the global void volume fraction a scatter in fatigue strength is identified.该研究提出了一种双尺度建模方法,可在宏观尺度上对碳纤维增强聚合物(CFRP)材料的微观机械缺陷特征进行有效的疲劳强度评估。该建模方法将宏观模型与考虑到空隙的微观机械模拟得出的有效弹性特性相结合。这样就能利用概率最弱环节法分析缺陷对材料疲劳强度的影响。研究了一种交叉层叠的 CFRP 层压材料。两个模拟案例研究证明了空隙含量和大小对特征疲劳强度的影响。对层压板进行了拉伸疲劳试验,验证了预测的数值行为。数值模型确定的特征疲劳强度差异与疲劳测试结果一致。通过数值得出的结论是,所研究的 CFRP 材料的疲劳强度受到空隙的影响,即使整体空隙体积分数只有微小差异,疲劳强度也会出现差异。Multiple blast resistance enhancement through negative-mass meta-honeycombs with multi-resonatorYao Huang, Jiu Hui Wu, Shao Kun Yang, Li Bo Wang, Fuyin Madoi:10.1016/j.compstruct.2023.117845通过多谐振器负质量元蜂窝增强多重抗爆能力Conventional honeycomb materials are difficult to resist multiple blast because the enormous energy generated by the explosion would cause plastic deformation of the material, which weakens the strength of the structure. In this paper, a novel meta-honeycomb is designed by adding local resonance system to hierarchical cells, which is based on the multi-resonator-enhanced bandgap property, to withstand multiple blast. This meta-honeycomb reverses the energy absorption mode of traditional honeycomb materials; that is, the energy absorption by plastic deformation of the material becomes the reflection of the stress wave through the equivalent negative mass property generated by the local resonance system, which significantly reduces the deformation of the material and the reaction force at the support under impact loads. In particular, for the secondary explosion loading, the maximum deformation of the meta-honeycomb is reduced by 74% compared with the traditional hierarchical honeycomb. Furthermore, it is demonstrated that the design of meta-honeycomb can be optimized by coupling the bandgap generated by the negative mass property, thereby improving the energy absorption efficiency. This research result provides a new concept for the design of blast-proof materials, which has a high potential for a wide range of engineering applications.传统的蜂窝材料很难抵御多重爆炸,因为爆炸产生的巨大能量会导致材料塑性变形,从而削弱结构的强度。本文基于多谐振器增强带隙特性,在分层单元中加入局部共振系统,设计出一种新型元蜂窝材料,以抵御多重爆炸。这种元蜂窝材料逆转了传统蜂窝材料的能量吸收模式,即通过局部共振系统产生的等效负质量特性,将材料塑性变形的能量吸收转变为应力波的反射,从而显著降低了冲击载荷下材料的变形和支撑处的反作用力。特别是在二次爆炸载荷下,元蜂窝的最大变形量比传统分层蜂窝减少了 74%。此外,研究还证明,通过耦合负质量特性产生的带隙,可以优化元蜂窝的设计,从而提高能量吸收效率。这项研究成果为防爆材料的设计提供了一个新概念,在广泛的工程应用中具有很大的潜力。High-Tg shape memory polyimide composites with “spot-plane” directional thermally conduction structure based on AlN nanoparticles and acidified grapheneXiaofei Wang, Yang He, Xinli Xiao, Wei Zhao, Jinsong Lengdoi:10.1016/j.compstruct.2023.117846基于氮化铝纳米颗粒和酸化石墨烯的具有 "点平面 "定向热传导结构的高 Tg 形状记忆聚酰亚胺复合材料In order to enhance the thermal conduction property and shorten response time of shape memory polyimide (SMPI), “spot-plane” directional thermally conductive acidified graphene/AlN/SMPI composites were prepared, in which AlN nanoparticles were used as “thermal conduction spots” and acidified graphene was used as two-dimensional “thermal conduction planes”. The SMPI composite doped with 6 wt% AlN and 0.8 wt% acidified graphene had good heat conducting properties (the in-plane thermal conductivity of 5.90 W m-1K-1), excellent mechanical propertied (the tensile strength of 134.5 MPa, and Young’s modulus of 3.8 GPa), high shape memory transition temperature (at 419 ℃), and great thermal stability and shape memory properties. Compared with SMPI resin matrix, the response time of the acidified graphene/AlN/SMPI composite was shortened by 140 s, only 20 s, and it can be applied in flexible electronics, intelligent response structures and active deformation structures in high-temperature environment.为了提高形状记忆聚酰亚胺(SMPI)的热传导性能并缩短其响应时间,制备了 "点-面 "定向导热酸化石墨烯/AlN/SMPI 复合材料,其中 AlN 纳米颗粒被用作 "热传导点",而酸化石墨烯被用作二维 "热传导面"。掺杂了 6 wt% AlN 和 0.8 wt% 酸化石墨烯的 SMPI 复合材料具有良好的导热性能(面内导热系数为 5.90 W m-1K-1)、优异的力学性能(拉伸强度为 134.5 MPa,杨氏模量为 3.8 GPa)、较高的形状记忆转变温度(419 ℃)以及较好的热稳定性和形状记忆性能。与 SMPI 树脂基体相比,酸化石墨烯/AlN/SMPI 复合材料的响应时间缩短了 140 秒,仅为 20 秒,可应用于高温环境下的柔性电子器件、智能响应结构和主动变形结构。Composites Part A: Applied Science and ManufacturingLiquid crystal/polymer composites for energy-efficient smart windows with a wide working temperature range and low off-axis hazeJianjun Xu, Zuowei Zhang, Longxiang He, Yingjie Shi, Yanzi Gao, Meina Yu, Huai Yangdoi:10.1016/j.compositesa.2023.107976 液晶/聚合物复合材料用于工作温度范围宽、离轴雾度低的节能智能窗As a type of intelligent dimming film, polymer dispersed liquid crystal (PDLC) films show attractive application prospects in field of smart windows. However, their current performance cannot meet the requirement of outdoor window applications, especially in severe conditions, such as poor shielding effect at high temperature, delayed response at low temperature and high off-axis haze. To simultaneously solve these problems, a PDLC film was prepared by optimizing the structure of acrylate crosslinking agent and birefringence of LC, which exhibits good shielding effects and contrast ratio (10) at high temperature of 100 °C, short rise time (0.16 s) and decay time (2.4 s) at low temperature of -30 °C, and a satisfying low off-axis haze (on-state haze < 10% at ±45°, on-state transmittance > 65% at ±60°). This study provides meaningful supplements for the application of PDLC film in outdoor smart windows, especially in automotive smart windows under extreme weather conditions.作为一种智能调光薄膜,聚合物分散液晶(PDLC)薄膜在智能窗户领域展现出诱人的应用前景。然而,目前其性能还不能满足户外窗户应用的要求,尤其是在恶劣条件下,如高温屏蔽效果差、低温响应延迟、离轴雾度大等。为了同时解决这些问题,研究人员通过优化丙烯酸酯交联剂的结构和 LC 的双折射,制备了一种 PDLC 薄膜,该薄膜在 100 ℃ 高温下具有良好的屏蔽效果和对比度(10),在 -30 ℃ 低温下具有较短的上升时间(0.16 秒)和衰减时间(2.4 秒),并且具有令人满意的低离轴雾度(±45° 时的通态雾度小于 10%,±60° 时的通态透射率大于 65%)。这项研究为 PDLC 薄膜在户外智能车窗,尤其是极端天气条件下的汽车智能车窗中的应用提供了有意义的补充。Significance of transcrystalline layer formation on electrical conductivity of polyamide 6-carbon nanotube nanocomposites: An experimental and theoretical studyMohammad Farhadpour, Javad Payandehpeyman, Mojtaba Mazaheri, Negar Irandoust, Gholamreza Pircheraghi, Reza Bagheridoi:10.1016/j.compositesa.2023.107977 跨晶层的形成对聚酰胺 6-碳纳米管纳米复合材料导电性的影响:实验与理论研究Electrical conductivity and mechanical properties of PA6/carbon nanofillers nanocomposites are highly dependent on the formation of PA6 transcrystalline layers onto the carbon nanofillers. In the current study, the substantial effects of PA6 viscosity and CNTs modification on transcrystalline layer formation in nanocomposites were investigated both experimentally and theoretically. FESEM, TEM, and solvent extraction observations showed almost identical morphological features for all samples, with well-dispersed carbon nanofillers within the matrix, and dispersed droplets morphology. Therefore, the differences in electrical conductivity among various nanocomposites were attributed to the only variable, which was differences in PA6 transcrystalline layer formation. It was found that employing high viscosity PA6, as well as modifying CNTs, both result in reduced transcrystalline layer formation and thus higher electrical conductivity, as corroborated by the theoretical modeling. Moreover, the evaluation of mechanical properties further elucidated that the transcrystalline layer formation can improve the tensile strength, Young’s modulus, and heat deflection temperature. Hence, on the one hand, transcrystalline layer formation endowed nanocomposites with superior mechanical properties due to the strong interfacial adhesion between the nanofillers and polymer matrix. On the other hand, however, it decreased the electrical conductivity by hindering electron tunneling through the dense and insulative transcrystalline layers.PA6/ 碳纳米填料纳米复合材料的导电性和机械性能在很大程度上取决于 PA6 在碳纳米填料上形成的透晶层。本研究从实验和理论两方面研究了 PA6 粘度和 CNTs 改性对纳米复合材料透晶层形成的实质性影响。FESEM、TEM 和溶剂萃取观察结果表明,所有样品的形态特征几乎相同,碳纳米填料在基体中分散良好,液滴形态分散。因此,各种纳米复合材料导电性能的差异可归因于唯一的变量,即 PA6 晶体层形成的差异。研究发现,采用高粘度 PA6 和对 CNT 进行改性都会减少透晶层的形成,从而提高导电率,这也得到了理论模型的证实。此外,对力学性能的评估进一步阐明,跨晶层的形成可提高拉伸强度、杨氏模量和热变形温度。因此,一方面,由于纳米填料与聚合物基体之间具有很强的界面粘附性,跨晶层的形成赋予了纳米复合材料优异的力学性能。但另一方面,它阻碍了电子通过致密和绝缘的跨晶层,从而降低了导电性。Composites Part B: EngineeringMechanical properties of hierarchical lattice via strain gradient homogenization approachHua Yang, Zhenkun Liu, Yi Xia, Wei Fan, Ambrose C Taylor, Xu Handoi:10.1016/j.compositesb.2023.111153 通过应变梯度均质化方法研究分层晶格的力学特性With the advancement of 3D printing technology, manufacturing metamaterials with extreme mechanical properties is becoming more feasible. Hierarchical lattices appear to be ideal candidates for obtaining desirable lightweight, high specific stiffness, and enhanced specific energy absorption. They can be constructed by architected substructures at multiple length scales. The interpretations of the underlying deformation mechanisms are necessary in order to manipulate with expected mechanical properties. In this paper, experiments were conducted to examine the effective mechanical behaviors of hierarchical lattice metamaterials. A strain gradient homogenization approach has been employed to correlate their morphological characteristics to the resulting material properties. The effective stiffness tensors are identified including the fourth-, fifth-, and sixth-order stiffness tensors. The higher-order inertial parameters are determined by a fitting procedure. Comparisons between direct finite element analyses and the homogenized strain gradient continua have been made for hierarchical lattice materials under static and dynamic loads. It is found that strain gradient homogenization approach can be an accurate, efficient and reliable way of predicting the mechanical behaviors of hierarchical lattice. A systematic analysis of geometrical parameters was conducted to uncover the underlying mechanisms responsible for the enhancement of effective properties. This work offers a novel approach for designing the mechanical properties of hierarchical metamaterials through precise control of secondary structure types and distributions.随着三维打印技术的发展,制造具有极端机械特性的超材料正变得越来越可行。分层晶格似乎是获得理想的轻质、高比刚度和增强比能量吸收的理想候选材料。它们可以通过多长度尺度的结构化子结构来构建。为了实现预期的机械性能,有必要对基本变形机制进行解释。本文通过实验研究了分层晶格超材料的有效力学行为。采用应变梯度均质化方法将其形态特征与由此产生的材料特性相关联。有效刚度张量包括四阶、五阶和六阶刚度张量。高阶惯性参数通过拟合程序确定。针对静态和动态载荷下的分层晶格材料,对直接有限元分析和均质化应变梯度连续体进行了比较。结果发现,应变梯度均质化方法可以准确、高效、可靠地预测分层晶格的力学行为。通过对几何参数进行系统分析,揭示了提高有效性能的内在机制。这项研究为通过精确控制次级结构类型和分布来设计分层超材料的力学性能提供了一种新方法。Cellulose-based ultrastrong wood adhesive and composites constructed through “sandwich” profile bonding interfaceTongda Liu, Guanben Du, Hongxing Yang, Kelu Ni, Hang Su, Haozhang Wen, Byung-Dae Park, Xin Ran, Wei Gao, Mizi Fan, Long Yangdoi:10.1016/j.compositesb.2023.111169 纤维素基超强木材粘合剂和通过 "三明治 "型材粘合界面构建的复合材料The present paper investigates the bonding interface between cellulose-based adhesive and chemically activated wood to explore the contribution of cohesion and interaction force between adhesive and substrate to the bonding properties. The activated wood surface rich in –NH2 groups is produced by brushing 3-amino-propyl triethoxysilane (APTES) on the natural wood. The amine-functionalized cellulose is made by grafting microcrystalline cellulose with APTES and the adhesive is developed by crosslinking the branched epoxide with the aminated cellulose. Subsequently, a super strong wood laminates is developed by reacting the –NH2 groups on the activated wood surface reacted with the epoxy groups in the adhesive to construct an “amino-epoxy-amino” sandwich bonding interface. The bonding strength of laminates at dry condition and after hot and boiling water treatment is 4.04 MPa, 2.42 MPa and 1.64 MPa, respectively. The strength after boiling water treatment of the plywood laminates made of all-component adhesive enhanced from 0 MPa to 1.64 MPa contrasted with that made of pure aminated cellulose and that prepared from the activated wood surface enhanced from 0.77 MPa to 1.64 MPa contrasted with that made by the nonactivated wood surface. The cohesion of the adhesive and the interaction force between the adhesive and the wood substrate played an important role in the bonding properties.本文研究了纤维素基粘合剂和化学活化木材之间的粘合界面,以探讨粘合剂和基材之间的内聚力和相互作用力对粘合性能的贡献。在天然木材上刷涂 3-氨基丙基三乙氧基硅烷(APTES)可产生富含 -NH2 基团的活化木材表面。胺功能化纤维素是通过将微晶纤维素与 APTES 接枝制成的,而粘合剂则是通过支链环氧化物与胺化纤维素交联制成的。随后,活化木材表面的 -NH2 基团与粘合剂中的环氧基团发生反应,构建出 "氨基-环氧-氨基 "夹层粘合界面,从而制成超强木质层压板。层压板在干燥状态下以及经过热水和沸水处理后的粘合强度分别为 4.04 兆帕、2.42 兆帕和 1.64 兆帕。与纯胺化纤维素胶合板相比,全成分胶合剂胶合板经沸水处理后的强度从 0 兆帕提高到 1.64 兆帕,活化木材表面制备的胶合板与非活化木材表面制备的胶合板相比,强度从 0.77 兆帕提高到 1.64 兆帕。粘合剂的内聚力以及粘合剂与木材基材之间的相互作用力对粘合性能起着重要作用。Composites Science and TechnologyEffects of exposure in seawater sea-sand concrete pore solution on fatigue performance of carbon FRP barsQi Zhao, Xiao-Ling Zhao, Daxu Zhang, Li-Ping Duandoi:10.1016/j.compscitech.2023.110418 暴露在海水海砂混凝土孔隙溶液中对碳玻璃钢条疲劳性能的影响The study aims to propose a methodology to predict the fatigue performance of carbon fiber-reinforced polymer (CFRP) bars under the seawater sea-sand concrete (SWSSC) environment. The effects of exposure in SWSSC pore solution on the fatigue damage mechanisms and fatigue performance of CFRP bars are presented. Firstly, the tensile fatigue tests of reference CFRP bars were performed under various stress levels with a constant stress ratio of 0.1. Secondly, the tensile fatigue tests of exposed CFRP bars subject to the simulated SWSSC pore solution were carried out. The tensile failure modes and fatigue damage mechanisms corresponding to different stress levels, were identified using scanning electron microscopy (SEM). Besides, the relationship between fatigue life expectancy and underlying fatigue damage mechanisms was carefully analyzed. Finally, the effective stress level method (ESLM) was proposed to evaluate the residual fatigue life of exposed CFRP bars based on the benchmark S–N curve. Combined with the degradation models (chemical etching/diffusion models) proposed in our previous research, ESLM could bridge corrosion fatigue life prediction of the exposed CFRP bars and the benchmark fatigue data of the non-exposed CFRP reinforcement. The predicted results have good correlations with the experimental data. This method can also provide valuable insight for the corrosion fatigue life prediction of other types of FRP composites.本研究旨在提出一种方法来预测碳纤维增强聚合物(CFRP)杆件在海水海砂混凝土(SWSSC)环境下的疲劳性能。介绍了暴露在 SWSSC 孔隙溶液中对 CFRP 杆件疲劳损伤机制和疲劳性能的影响。首先,在 0.1 恒定应力比的不同应力水平下对 CFRP 棒材进行了拉伸疲劳试验。其次,对暴露在模拟 SWSSC 孔隙溶液中的 CFRP 杆件进行了拉伸疲劳试验。使用扫描电子显微镜(SEM)确定了不同应力水平对应的拉伸失效模式和疲劳损伤机制。此外,还仔细分析了疲劳寿命与潜在疲劳损伤机制之间的关系。最后,根据基准 S-N 曲线,提出了有效应力水平法(ESLM)来评估裸 露 CFRP 杆件的残余疲劳寿命。结合之前研究中提出的降解模型(化学蚀刻/扩散模型),ESLM 可以将裸 露 CFRP 钢筋的腐蚀疲劳寿命预测与非裸 露 CFRP 钢筋的基准疲劳数据进行桥接。预测结果与实验数据具有良好的相关性。该方法还能为其他类型玻璃钢复合材料的腐蚀疲劳寿命预测提供有价值的见解。来源:复合材料力学仿真Composites FEM

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