首页/文章/ 详情

【新文速递】2023年12月31日复合材料SCI期刊最新文章

24天前浏览624

今日更新:Composite Structures 6 篇,Composites Part B: Engineering 1 篇,Composites Science and Technology 1 篇

Composite Structures

Fatigue damage reconstruction in glass/epoxy composites via thermal analysis and machine learning: A theoretical study

Rodrigo Q. Albuquerque, Ali Sarhadi, Martin Demleitner, Holger Ruckdäschel, Martin A. Eder

doi:10.1016/j.compstruct.2023.117855

通过热分析和机器学习重建玻璃/环氧复合材料的疲劳损伤:理论研究

This study introduces an advanced, non-contact diagnostic tool for structural health monitoring of fatigue damage in fiber/polymer composite materials. The approach combines thermal image recognition of fatigue self-heating hotspots with high-fidelity thermal modeling to quantitatively assess subsurface fatigue damage distributions by machine learning. To this end, artificial thermal images are generated through 3D numerical thermal analysis of an inherent fatigue damage heat source within a glass/epoxy composite, derived from sampling a multivariate Gaussian distribution of microcracks. Subsequently, these synthetic thermal images are employed to train three distinct regression models: a convolutional neural network, a Gaussian processes regressor, and a straightforward least squares model. Various image augmentation techniques are applied to expand the dataset efficiently. All models accurately predict the size of the damage and - most importantly - the maximum temperature within the damage deep inside the composite. The regression methods estimate the diagonal elements of covariance matrix components of the Gaussian distribution, with accuracies ranging from 86% to 99%. The findings presented in this work contribute to establishing a solid foundation for non-destructive subsurface fatigue damage assessment in composite materials, with many practical applications in experimental composites fatigue research.

本研究介绍了一种先进的非接触式诊断工具,用于纤维/聚合物复合材料疲劳损伤的结构健康监测。该方法将疲劳自热热点的热图像识别与高保真热建模相结合,通过机器学习定量评估次表层疲劳损伤分布。为此,通过对玻璃/环氧树脂复合材料内部固有的疲劳损伤热源进行三维数值热分析,生成人工热图像,该热图像由微裂纹的多元高斯分布采样得出。随后,利用这些合成热图像训练三种不同的回归模型:卷积神经网络、高斯过程回归器和直接最小二乘法模型。应用各种图像增强技术有效地扩展了数据集。所有模型都能准确预测损伤的大小,最重要的是能准确预测复合材料内部损伤深处的最高温度。回归方法估算了高斯分布协方差矩阵成分的对角线元素,准确率在 86% 到 99% 之间。这项研究成果为复合材料次表层疲劳损伤的无损评估奠定了坚实的基础,在复合材料疲劳实验研究中有着广泛的实际应用。


Experiment and finite element analysis of protective honeycombs based on equivalent method for ocean engineering under impact loading

Yunfei Qu, Jingjing Chen, Lei Jiao, Tianzhuang Ye, Xinchao Hu

doi:10.1016/j.compstruct.2023.117858

基于等效法的海洋工程冲击荷载下保护蜂窝的实验和有限元分析

Aiming at reducing damage between ship berthing and high-pressure vessels, the protective honeycomb filled with Roller Arrowhead Wings Honeycomb (RAWH) was constructed based on equivalent method. A novel Double Arrowhead Wings Honeycomb (DAWH), inspired by Tilia Platyphylloswas, was proposed for arrangement in RAWH. The analytical models were derived with size factor n for honeycomb selection and design. The mechanical properties, energy absorption, compression response, structure efficiency, and deformation mode of RAWH were investigated by Finite Element Analysis (FEA) and Experiment (EXP), comparing with Roller Hexagonal Honeycomb (RHH), Roller Re-entrant Honeycomb (RRH), and Roller Solid. With particular calculation methods, the work energy absorption, engineering strain, and engineering stress were obtained within acceptable error compared to finite element analysis. The contact force of RAWH exceeded RHH, RRH and Solid about 1.7, 5 , and 0.32 times, with a maximum of 15000 N. Further, the deformation modes of RAWH were discussed and recorded with “V” mode and “U” mode appearing special characteristics of enhancement and resilience. The equivalent Poisson’s ratios for protective honeycombs were studied and described in the Morgan-Mercer-Flodin (MMF) growth model with the phenomena of “Step Fluctuation”, “Inter-layer Progression” and “Step Stability”. These results, methods, and discussions might bring significance for reducing damage from collisions in ocean engineering.

为了减少船舶停泊和高压船舶之间的损害,根据等效方法建造了填充有滚动箭翼蜂窝(RAWH)的保护蜂窝。受椴树(Tilia Platyphylloswas)的启发,提出了一种新型双箭头蜂窝(DAWH),用于在 RAWH 中布置。在蜂窝的选择和设计中,利用尺寸系数 n 得出了分析模型。通过有限元分析(FEA)和实验(EXP)研究了 RAWH 的力学性能、能量吸收、压缩响应、结构效率和变形模式,并与滚筒六角蜂窝(RHH)、滚筒再入蜂窝(RRH)和滚筒实心进行了比较。与有限元分析相比,采用特定计算方法得出的功耗吸收、工程应变和工程应力误差在可接受范围内。此外,还讨论并记录了 RAWH 的变形模式,其中 "V "模式和 "U "模式具有增强和回弹的特点。研究了保护性蜂窝的等效泊松比,并在摩根-默塞尔-弗洛丁(MMF)生长模型中描述了 "阶跃波动"、"层间渐进 "和 "阶跃稳定 "现象。这些结果、方法和讨论可能对减少海洋工程中的碰撞损害具有重要意义。


Characterizing compressive failure mechanisms and their transitions in woven composites under on and off-axis loading

Leana Grotz, Kedar Kirane

doi:10.1016/j.compstruct.2023.117848

表征编织复合材料在轴向和非轴向加载条件下的压缩破坏机理及其转变过程

The compressive failure of fiber-reinforced composites is complex, occurring via multiple mechanisms depending on the loading angle with the fiber directions. This work is aimed at the detailed characterization and understanding of this dependence in a 2 × 2 epoxy/carbon twill woven composite. Reported are the results of a variety of on-axis and off-axis compressive tests with loading angles ranging from 0°to 45°, carried out as per ASTM standards. The tests show that for angles from 0°to 10°, no appreciable change in compressive strength occurs. Failure in the load aligned tows is dominated by out of plane brittle shear failure and out of plane fiber kinking. The behavior is very brittle, consisting of a sharp peak load immediately dropping to a non-zero residual stress plateau. Extensive micro-cracking in the transverse tow is also observed. Between 10°and 25°many transitions occur, including increased ductility, pre-peak non-linearity, increasing width of the out-of-plane fiber kink band, more gradual post-peak load decrease, and an increase in the residual stress. The lowest strength occurs at 45°where the behavior is completely ductile and failure occurs by in-plane fiber kink band formation. A correlation between the in-plane shear stress and kink band width appears to exist. The maximum stress based strength envelope theory captures this loading angle dependence of strength. The findings are crucial for designing multi-directional woven composite laminates subjected to compressive loading, and for the validation of computational models.

纤维增强复合材料的压缩失效过程十分复杂,根据加载角度与纤维方向的不同,会出现多种失效机制。这项研究旨在详细描述和理解 2 × 2 环氧树脂/碳斜纹编织复合材料的这种依赖性。报告根据 ASTM 标准,在加载角度为 0° 至 45° 的范围内进行了各种轴上和轴下压缩试验。试验结果表明,在 0° 至 10° 的角度范围内,抗压强度没有明显变化。负载对齐纤维束的破坏主要是平面外脆剪破坏和平面外纤维扭结。这种行为非常脆,包括一个急剧的峰值载荷,然后立即下降到一个非零残余应力平台。横向纤维束中也出现了广泛的微裂纹。在 10° 和 25° 之间出现了许多转变,包括延展性增加、峰值前非线性、平面外纤维扭结带宽度增加、峰值后载荷下降更渐进以及残余应力增加。在 45° 处强度最低,其行为完全是延展性的,通过面内纤维扭结带的形成而发生破坏。面内剪切应力与扭结带宽度之间似乎存在相关性。基于最大应力的强度包络理论捕捉到了强度的这种加载角度依赖性。这些发现对于设计承受压缩载荷的多向编织复合材料层压板以及验证计算模型至关重要。


Variable kinematics finite plate elements for the buckling analysis of sandwich composite panels

G. Di Cara, M. D’Ottavio, O. Polit

doi:10.1016/j.compstruct.2023.117856

用于夹层复合板屈曲分析的可变运动学有限板元素

This paper extends sublaminate-based variable kinematics plate finite elements towards the buckling analysis of composite structures. Robust locking-free 4-node and 8-node interpolations are used to build the finite element matrices in terms of fundamental nuclei, invariant with respect to the employed kinematic model of the composite plate. Geometric nonlinearities are accounted for in the von Kármán sense. The classical linearised stability analysis is mainly conducted for sandwich panels, for which different kinematic assumptions are employed for the skins and the core. Global buckling of the sandwich panel as well as short-wavelength wrinkling of the skins are investigated by referring to a variety of case studies, including homogeneous and laminated skins as well as isotropic and orthotropic cores. Convergence studies are performed to establish the minimum number of elements for the local instabilities to be grasped. The proposed computational framework requires a simple 2D mesh and is capable of providing quasi-3D response patterns. This is as demonstrated by numerous case studies that address the transition from global to local buckling, the onset of wrinkling in flat sandwich panels with anisotropic skins under various loading conditions as well as the local face sheet instability occurring in sandwich panels working in bending. It is concluded that he proposed FEM-based tool is computationally efficient and can be advantageously employed in pre-sizing design phases without resorting to full 3D models.

本文将基于子层状可变运动学的板有限元扩展到复合材料结构的屈曲分析。使用稳健的无锁定 4 节点和 8 节点插值来构建基本核的有限元矩阵,该矩阵与所使用的复合板运动学模型无关。在 von Kármán 意义上考虑了几何非线性因素。经典的线性化稳定性分析主要是针对夹芯板进行的,对表皮和夹芯采用了不同的运动学假设。通过参考各种案例研究,包括均质和层状表皮以及各向同性和正交各向异性夹芯,对夹芯板的整体屈曲以及表皮的短波起皱进行了研究。通过收敛性研究,确定了把握局部不稳定性的最小元素数量。所提出的计算框架只需简单的二维网格,就能提供准三维响应模式。大量案例研究证明了这一点,这些案例研究涉及从整体屈曲到局部屈曲的过渡、各向异性表皮的平面夹层板在各种加载条件下开始起皱以及夹层板在弯曲状态下发生的局部面片不稳定性。最后得出的结论是,基于有限元的工具计算效率高,可在尺寸预设设计阶段发挥优势,而无需求助于完整的三维模型。


Overcoming the brittleness of shear failure: A new FRP-RSC strengthening philosophy

Weiwen Li, Meizhong Wu, Biao Hu, Peng Wang

doi:10.1016/j.compstruct.2023.117857

克服剪切破坏的脆性:FRP-RSC 加固新理念

Due to the linear elastic stress-strain behavior of carbon fiber reinforced polymer (CFRP), the ductility of CFRP shear-strengthened reinforced concrete (RC) beams will be significantly reduced. Compared with shear capacity enhancement, increasing the ductility of CFRP shear-strengthened RC members is a much more challenging task, and a satisfactory solution has yet to be found. This paper introduces a new methodology that combines the brittle fiber reinforced polymer (FRP) with ductile rubber support composite (RSC) to form the FRP-RSC strengthening system. The variable stiffness RSC can adjust the stiffness of the strengthening system, which is achieved by the changed shear transfer actions in FRP, transverse reinforcement and concrete. Eight specimens were tested to evaluate the effectiveness of the FRP-RSC strengthening method. Experimental tests demonstrated that the displacement ductility with this FRP-RSC technique was 2.15 times that of the conventional externally bonded (EB) FRP strengthening, reaching remarkably 5.24. The mechanisms for enhancements in ductility, deformability and shear capacity were revealed. Poor matches were observed between the predicted FRP shear strength contribution (Vf) per existing models and test data. A new model that can predict Vf of FRP-RSC strengthened RC beams was developed, and better agreements between predictions and experimental results were obtained.

由于碳纤维增强聚合物(CFRP)的线性弹性应力-应变行为,CFRP 剪力加固钢筋混凝土(RC)梁的延性将显著降低。与提高抗剪能力相比,提高 CFRP 剪力加固钢筋混凝土构件的延性是一项更具挑战性的任务,目前尚未找到令人满意的解决方案。本文介绍了一种新方法,它将脆性纤维增强聚合物(FRP)与延性橡胶支撑复合材料(RSC)相结合,形成 FRP-RSC 加固系统。可变刚度 RSC 可以调节加固系统的刚度,通过改变 FRP、横向钢筋和混凝土中的剪切传递作用来实现。为评估 FRP-RSC 加固方法的效果,对八个试件进行了测试。实验证明,FRP-RSC 技术的位移延性是传统外部粘结(EB)FRP 加固技术的 2.15 倍,达到了显著的 5.24 倍。实验还揭示了延展性、变形性和剪切能力的增强机制。根据现有模型预测的玻璃钢剪切强度贡献率(Vf)与试验数据之间的匹配度较低。开发了一种可预测 FRP-RSC 加固 RC 梁 Vf 的新模型,并获得了预测与试验结果之间更好的一致性。


Composite anisogrid lattice toroidal shell: Application to a load-carrying rim of the spacecraft reflectarray antenna

E.V. Morozov, A.V. Lopatin, A.V. Shatov, Z.A. Kazantsev

doi:10.1016/j.compstruct.2023.117860

复合异构格栅环形壳:应用于航天器反射阵列天线的承载边缘

A novel design of the composite transformable/foldable rim of the spacecraft reflectarray antenna is presented in the paper. The rim is made in the form of anisogrid lattice toroidal shell split into six parts that are jointed using hinges containing helical springs. The springs create the moments required to deploy the antenna in orbit. A dielectric flexible flat membrane with reflective radiating elements generating a radio signal with required directivity is stretched on the rim. An algorithm of the finite-element model generation is developed for the toroidal rim using a typical finite-element unit cell of lattice structure. The lattice toroidal shell is modelled as a three-dimensional frame composed of curvilinear ribs. The results of design analysis of the lattice rim delivering a minimal mass to its structure subject to constraints imposed on the fundamental frequency, values of stress, and the buckling load factor are presented in this work. The corresponding set of design parameters of lattice structure, including the angle of orientation of helical ribs, number of helical ribs of one orientation, and size of the ribs’ cross section are identified based on these results.

本文介绍了航天器反射阵列天线复合可变/可折叠边缘的新型设计。边框采用异方格网环形壳体的形式,分成六个部分,使用含有螺旋弹簧的铰链连接。弹簧产生在轨道上展开天线所需的力矩。一个带有反射辐射元件的介质柔性平膜被拉伸到边缘上,产生具有所需指向性的无线电信号。使用典型的晶格结构有限元单元,为环形边缘开发了有限元模型生成算法。晶格环形外壳被模拟为由曲线肋条组成的三维框架。本研究介绍了在基频、应力值和屈曲载荷系数的限制条件下,为其结构提供最小质量的晶格轮缘的设计分析结果。根据这些结果,确定了相应的格状结构设计参数集,包括螺旋肋的取向角、一个取向的螺旋肋数量以及肋的横截面尺寸。


Composites Part B: Engineering

A deep material network approach for predicting the thermomechanical response of composites

Dongil Shin, Ryan Alberdi, Ricardo A. Lebensohn, Rémi Dingreville

doi:10.1016/j.compositesb.2023.111177

预测复合材料热机械响应的深度材料网络方法

Recent progress combining micromechanics and machine learning holds promise for accurately and rapidly predicting the mechanical behavior of complex composite materials. This study extends the Deep Material Network (DMN), a binary-tree network trained on linear direct-numerical-simulation data, to predict the thermo-elasto-viscoplastic behavior of composites. This extension incorporates the thermal expansion properties homogenization into the network’s building blocks and expands the online formulation to consider thermal boundary conditions. By comparing various implementations of these building blocks, we demonstrate the network’s extrapolation to thermomechanical problems. We then show how this extended DMN can be applied to uncertainty quantification and inverse design problems.

结合微观力学和机器学习的最新进展有望准确、快速地预测复杂复合材料的力学行为。本研究扩展了深度材料网络(DMN)--一种基于线性直接数值模拟数据训练的二叉树网络,用于预测复合材料的热弹性-粘弹性行为。这一扩展将热膨胀特性均质化纳入了网络的构建模块,并扩展了在线公式,以考虑热边界条件。通过比较这些构件的各种实现方式,我们展示了该网络对热力学问题的推断能力。然后,我们展示了如何将这一扩展 DMN 应用于不确定性量化和逆向设计问题。


Composites Science and Technology

Tailoring flexible-segment-rich resin network structure by multi-step copolymerization for improved composite bipolar plate of proton exchange membrane fuel cell

Jing Chen, Nan Qin, Liming Jin, Xiangmin Pan, Junsheng Zheng, Pingwen Ming, Cunman Zhang, Jim P. Zheng

doi:10.1016/j.compscitech.2023.110422

 

通过多步共聚,定制富含柔性片段的树脂网络结构,改进质子交换膜燃料电池的复合双极板

Composite bipolar plates composed of conductivity fillers and resins are widely employed in stationary proton exchange membrane fuel cell (PEMFC) due to their high corrosion resistance in acidic environments. Phenol-formaldehyde resin is a commonly used adhesive in composite bipolar plates; while numerous benzene rings in phenol-formaldehyde resin result in the poor flexibility of composite bipolar plates. Embedding the flexible segment (–CHOH–CH2-O-) in the resin network structure of phenol-formaldehyde resin by copolymerization with epoxy resin is an effective method for improving the defects of phenol-formaldehyde resin. In this contribution, to tailor flexible-segment-rich (–CHOH–CH2-O-) resin network structure, the co-polymerization mechanism of phenol-formaldehyde resin and epoxy resin is investigated in detailed by in-situ Fourier Transform Infrared (FTIR), based on which an Alter-T strategy is proposed for flexible-segment-rich (–CHOH–CH2-O-) resin network structure during composite bipolar plates fabrication process. The obtained composite bipolar plates consisted of graphite and flexible-segment-rich resin network structure delivers improved flexural strength (86.97 MPa), electrical conductivity (203.22 S cm−1) and areal resistance (3.41 mΩ cm2) in comparison to previously reported composite bipolar plates with same components, which are also over the technical standard of the DOE. It is further demonstrated that enriching the flexible segment for improving the poor flexibility of resin network structure is of great importance to enhance the performance of the composite bipolar plates.

由导电填料和树脂组成的复合双极板因其在酸性环境中的高耐腐蚀性而被广泛应用于固定式质子交换膜燃料电池(PEMFC)。苯酚-甲醛树脂是复合双极板中常用的粘合剂,但苯酚-甲醛树脂中含有大量苯环,导致复合双极板的柔韧性较差。通过与环氧树脂共聚,在酚醛树脂的树脂网络结构中嵌入柔性段(-CHOH-CH2-O-)是改善酚醛树脂缺陷的有效方法。为定制富含柔性段(-CHOH-CH2-O-)的树脂网络结构,本文通过原位傅立叶变换红外光谱(FTIR)详细研究了酚醛树脂与环氧树脂的共聚机理,并在此基础上提出了在复合双极板制造过程中实现富含柔性段(-CHOH-CH2-O-)树脂网络结构的 Alter-T 策略。与之前报道的相同成分的复合双极板相比,所获得的由石墨和富柔性段树脂网络结构组成的复合双极板的抗弯强度(86.97 MPa)、导电率(203.22 S cm-1)和电阻率(3.41 mΩ cm2)均有所提高,且均超过了 DOE 的技术标准。研究进一步证明,增加柔性段以改善树脂网络结构柔性差的问题,对提高复合双极板的性能具有重要意义。



来源:复合材料力学仿真Composites FEM
ACTMechanicalSystemInspireDeform疲劳复合材料碰撞非线性燃料电池航天船舶海洋裂纹理论材料试验
著作权归作者所有,欢迎分享,未经许可,不得转载
首次发布时间:2024-11-05
最近编辑:24天前
Tansu
签名征集中
获赞 6粉丝 0文章 776课程 0
点赞
收藏
作者推荐

【新文速递】2024年1月1日固体力学SCI期刊最新文章

今日更新:Mechanics of Materials 1 篇,International Journal of Plasticity 2 篇,Thin-Walled Structures 1 篇Mechanics of MaterialsEffect of the sonic shock wave on void evolution in materials under irradiationNing Zhou, YinBo Zhu, HengAn Wudoi:10.1016/j.mechmat.2023.104907 声波冲击波对辐照下材料空隙演变的影响Understanding the void-cascade interaction is of great importance for clarifying the irradiation damage as a major challenge in nuclear industry, since it typically causes void annihilation or shrinkage, which greatly affects the swelling of irradiated materials. But the current understanding of it is extremely limited due to the neglect of the sonic shock wave. Herein, we take γ-U as the representative model due to the emergence of a violent sonic shock wave there. Molecular dynamics simulations are performed to explore the underlying mechanism of the sonic shock wave interacting with voids. It is firstly revealed that the sonic shock wave is essentially focusons along <111> crystal orientation family, attributed to the highest energy transfer efficiency along <111> in γ-U. These focusons can cause void annihilation or shrinkage via sliding, while thermal spikes only cause annihilation by covering voids. Combining these two factors, we propose a model to qualitatively epitomize the void-cascade interaction, in which the influence scope exhibits an intriguing anisotropic feature, overturning a long-accepted view that the void-cascade interaction is isotropic. This model is further generalized to other nuclear materials owing to the similar mechanism of the sonic shock wave. Moreover, we find distinct size effect of voids on void-cascade interaction. Thermal spikes hardly affect voids that are too large to be covered, while the sonic shock wave also causes visible shrinkage in large voids. The present work proves that the sonic shock wave has a non-negligible effect on void evolution, improving the fundamental understanding of void-cascade interaction in irradiated materials.空隙-级联相互作用通常会导致空隙湮灭或收缩,从而极大地影响辐照材料的膨胀,因此了解空隙-级联相互作用对于澄清辐照损伤这一核工业领域的重大挑战具有重要意义。但由于忽视了声波冲击波,目前对它的认识极为有限。在此,我们以γ-U 为代表模型,因为那里出现了剧烈的声波冲击波。通过分子动力学模拟来探索声波冲击波与空隙相互作用的内在机理。研究首先揭示了声波冲击波本质上是沿 <111> 晶向系列的焦子,这归因于在 γ-U 中沿 <111> 晶向的能量传递效率最高。这些聚焦子可以通过滑动造成空隙湮灭或收缩,而热尖峰只能通过覆盖空隙造成湮灭。结合这两个因素,我们提出了一个模型来定性地表征空隙-级联相互作用,其中的影响范围呈现出令人感兴趣的各向异性特征,推翻了长期以来公认的空隙-级联相互作用各向同性的观点。由于音速冲击波的机制类似,这一模型还可进一步推广到其他核材料。此外,我们还发现空隙的大小对空隙-级联相互作用有明显的影响。热尖峰几乎不会影响大到无法覆盖的空隙,而声波冲击波也会导致大空隙的明显收缩。本研究证明了声波冲击波对空隙演变具有不可忽视的影响,从而提高了对辐照材料中空隙-级联相互作用的基本认识。International Journal of PlasticityAchieving exceptional work-hardening capability of additively-manufactured multiphase Fe-Mn alloys via multiple deformation mechanismsPeifeng Liu, Qinyuan Huang, Quan Shan, Zengbao Jiao, Qingge Wang, Yang Ma, Runhua Zhou, Ian Baker, Hong Wudoi:10.1016/j.ijplas.2023.103871 通过多种变形机制实现快速成型多相铁-锰合金的超强加工硬化能力Laser-powder-bed-fusion (LPBF) fabricated Fe-Mn biodegradable alloys provide an attractive prospect for orthopedic applications due to their good tensile strength and high degradation rate. Nevertheless, the ε-martensite and heterogeneous microstructures produced by the LPBF processing often lead to premature failure of alloys. Herein, we report a LPBFed multiphase Fe-18Mn alloy (γ-austenite, ε-martensite, and α-ferrite) fabricated from pre-alloyed powders. After annealing at 650 °C, the alloy with a uniform microstructure displays a high 1 GPa tensile strength, a good fracture elongation of 16 %, and an extremely high work-hardening rate of 8500 MPa. The work-hardening rate is higher than that reported in most Fe-Mn steels and Fe-based high entropy alloys. The grain size of a few hundred nanometers provided the excess Gibbs free energy, resulting in an increase in the stacking fault energy (SFE) to 23.9 mJ/m2. The multiple deformation mechanisms, i.e., SFs, the martensitic transformation (γ → ε → α') and nano-deformation twins (DTs), were sequentially activated. We elucidate such unique work-hardening capability, originating from the interaction between the DTs, SFs and transformed martensite. Besides a high-density of dislocations were accumulated between parallel planar defects, the cooperative deformation of the soft and hard phases provided continuous hardening. Our findings highlight the exceptional work-hardening capability of additively-manufactured Fe-Mn alloys achieved by a multiphase material exhibiting multiple deformation mechanisms. The work also provides a straightforward approach for the development of stable-implanted Fe-based bone substitutes.激光粉末床熔融(LPBF)制造的铁锰生物可降解合金具有良好的抗拉强度和较高的降解率,为矫形外科应用提供了诱人的前景。然而,LPBF加工过程中产生的ε-马氏体和异质微结构往往会导致合金过早失效。在此,我们报告了一种由预合金化粉末制成的 LPBFed 多相铁-18Mn 合金(γ-奥氏体、ε-马氏体和 α-铁素体)。在 650 °C 退火后,具有均匀微观结构的合金显示出较高的 1 GPa 抗拉强度、16 % 的良好断裂伸长率和 8500 MPa 的极高加工硬化率。该加工硬化率高于大多数铁锰钢和铁基高熵合金的加工硬化率。几百纳米的晶粒尺寸提供了过剩的吉布斯自由能,导致堆叠断层能(SFE)增加到 23.9 mJ/m2。多种变形机制,即 SFs、马氏体转变(γ → ε → α')和纳米变形孪晶(DTs)依次被激活。我们阐明了这种独特的加工硬化能力,它源于 DTs、SFs 和转化马氏体之间的相互作用。除了在平行平面缺陷之间积累了高密度位错之外,软硬相的协同变形还提供了持续硬化。我们的研究结果凸显了加成法制造的铁锰合金通过表现出多种变形机制的多相材料实现的卓越加工硬化能力。这项研究还为开发稳定的植入式铁基骨替代物提供了一种直接的方法。Distinct avalanche dynamics detected in metallic glasses with high energy state revealing the crack-like shear banding mechanismKai Tao, Fucheng Li, Yanhui Liu, Eloi Pineda, Kaikai Song, Jichao Qiaodoi:10.1016/j.ijplas.2023.103873在金属玻璃中探测到的高能态雪崩动力学揭示了类似裂纹的剪切带机制When a sufficiently high stress is applied to a metallic glass, causing plastic deformation, the material undergoes structural reconfiguration through dissipative slip avalanche events that release local stresses. By utilizing isothermal annealing and cold rolling techniques to tune the energy levels of metallic glasses, it has been observed that structural rejuvenation is accompanied by structural relaxation, as evidenced by distinct changes in avalanche dynamics. We present detailed statistics of the avalanche dynamics during shear band formation in energy-tuned metallic glasses, ranging from structurally relaxed to rejuvenated states. By analyzing shear band characteristics and examining scaling exponents, avalanche durations, and stress relaxation rates, we can establish a connection between the local activation of shear transformation zones and the formation of macroscopic shear bands. The statistics of avalanche duration indicate that an increase in soft zones within metallic glasses can alleviate stress release and stabilize plastic flow, as evidenced by the characteristics of shear bands. We attribute the significant transition of serrated flow, observed at different energy levels (i.e., as-cast, relaxed, and rejuvenated states) to the variations in nucleation and multiplication of shear bands that originate from local weak spots. Analysis of the distinct avalanche dynamics suggests that in lower energy level metallic glasses, the nucleation and propagation of shear bands exhibit localized crack-like behavior, while in higher energy level metallic glasses, they display diffused crack-like characteristics. Indeed, our results strongly support that the decreased avalanches observed in the high energy level metallic glasses originate from the nucleation of numerous small shear bands, which directly compete with the propagation of the main local shear band. These findings deepen our fundamental understanding of the relationship between the microscopic mechanism of slip avalanche dynamics and shear banding, providing a pathway to control the plasticity of metallic glasses.当对金属玻璃施加足够大的应力导致塑性变形时,材料会通过释放局部应力的耗散滑移雪崩事件进行结构重构。通过利用等温退火和冷轧技术调节金属玻璃的能级,我们观察到结构年轻化伴随着结构松弛,雪崩动力学的明显变化就是证明。我们介绍了能量调谐金属玻璃剪切带形成过程中雪崩动力学的详细统计数据,包括从结构松弛状态到年轻化状态。通过分析剪切带特征并研究缩放指数、雪崩持续时间和应力松弛率,我们可以建立剪切转换区局部激活与宏观剪切带形成之间的联系。雪崩持续时间的统计结果表明,金属玻璃内部软区的增加可以缓解应力释放并稳定塑性流动,剪切带的特征也证明了这一点。我们认为,在不同能级(即铸造态、松弛态和恢复态)下观察到的锯齿流的显著转变是由于局部薄弱点产生的剪切带的成核和增殖变化造成的。对不同雪崩动力学的分析表明,在低能级金属玻璃中,剪切带的成核和传播表现出局部裂纹状行为,而在高能级金属玻璃中,则表现出扩散裂纹状特征。事实上,我们的研究结果有力地证明,在高能级金属玻璃中观察到的雪崩现象的减少源于无数小剪切带的成核,这些剪切带与主要局部剪切带的传播直接竞争。这些发现加深了我们对滑动雪崩动力学微观机制与剪切带之间关系的基本理解,为控制金属玻璃的塑性提供了一条途径。Thin-Walled StructuresWave propagation in beams with functionally graded porosity distribution under highly transient axial and transverse impactsM. Heshmati, S.K. Jalali, N.M. Pugnodoi:10.1016/j.tws.2023.111548在高瞬态轴向和横向冲击下,具有功能分级孔隙分布的梁中的波传播Recent advances in the manufacturing process provide a possibility of fabricating a new generation of porous materials denoted by functionally graded porous materials (FGPM). This paper aims to present a time domain analysis of wave propagation through the porous structures with functionally graded porosity distribution, which has not been completely studied before. For this purpose, the beams with different functionally graded porosity distributions subjected to both axial and transverse tip impact loads with a high-frequency content are investigated. The shear deformable cantilevered functionally graded porous beams with various porosity distributions through the beam thickness are studied. The governing differential equations are derived using the Hamiltonian principle based on the Timoshenko beam theory. A locking-free first-order shear deformable beam element is used to derive the finite element formulation of the equations. The Newmark time integration method is used to perform a time domain analysis of the equations of motion and to investigate the transient response of the beams. The axial and transverse wave propagation characteristics through functionally graded (FG) porous beams are found using time domain analysis of the results. Deflection and velocity time histories of the tip and each point of the beam, reflection time, and variation of support reactions are obtained. The influences of the porosity magnitude and porosity distribution on the wave propagation characteristics and overall time responses are investigated. The results reveal that porosity distribution has a significant effect on the wave amplitude, wave speed, and reflection from the boundary. Also, this study can help in a better understanding of porous structures' behavior subjected to high-transient impact loads in different engineering applications.制造工艺的最新进展为制造新一代多孔材料提供了可能,这种材料被称为功能分级多孔材料(FGPM)。本文旨在对波在具有功能分级孔隙率分布的多孔结构中的传播进行时域分析,而这在以前还没有过完整的研究。为此,本文研究了具有不同功能分级孔隙率分布的横梁,这些横梁同时承受轴向和横向尖端高频冲击载荷。研究了在梁厚度上具有不同孔隙率分布的可剪切变形悬臂功能分级多孔梁。基于季莫申科梁理论,利用哈密顿原理推导出了控制微分方程。无锁定一阶剪切变形梁元素用于推导方程的有限元公式。采用纽马克时间积分法对运动方程进行时域分析,并研究梁的瞬态响应。通过对结果进行时域分析,发现了穿过功能分级(FG)多孔梁的轴向和横向波传播特性。得出了梁顶端和各点的挠度和速度时间历程、反射时间以及支撑反作用力的变化。研究了孔隙率大小和孔隙率分布对波传播特性和整体时间响应的影响。结果表明,孔隙率分布对波幅、波速和边界反射有显著影响。此外,这项研究还有助于更好地理解多孔结构在不同工程应用中承受高瞬态冲击载荷时的行为。来源:复合材料力学仿真Composites FEM

未登录
还没有评论
课程
培训
服务
行家
VIP会员 学习 福利任务 兑换礼品
下载APP
联系我们
帮助与反馈