首页/文章/ 详情

【新文速递】2023年11月18日固体力学SCI期刊最新文章

24天前浏览662

今日更新:International Journal of Solids and Structures 1 篇,Mechanics of Materials 1 篇,Thin-Walled Structures 2 篇

International Journal of Solids and Structures

Multiscale modeling and simulation on mechanical behavior of fiber reinforced concrete

Li Xiang-Nan, Zuo Xiao-Bao, Li Liang, Liu Jing-Han

doi:10.1016/j.ijsolstr.2023.112569

纤维增强混凝土力学行为的多尺度建模与模拟

A multiscale mechanical model is proposed to quantitatively describe the macro-mechanical behavior of fiber reinforced concrete (FRC) based on its multiscale material compositions. Firstly, according to the actual scale characteristics of compositions, the model of composite material at each scale of FRC, including hardened cement paste, cement mortar and meso-FRC, was geometrically reconstructed; Secondly, the equations of stiffness and strength of composite material at each scale were established by using the equivalent inclusion theory and Ottosen failure criterion, and a multiscale mechanical model of FRC was proposed by upscaling from stiffness and strength of microstructure to macro-mechanical behavior of FRC; Finally, after verified by the experimental results in the literature, the proposed model was used to numerically investigate the loading-induced stress response and the evolution of macro-mechanical properties of FRC in its curing process, as well as the influence of steel fiber parameters, such as volume fraction, aspect ratio and spatial orientation, on the mechanical properties of FRC.

根据纤维增强混凝土(FRC)的多尺度材料组成,提出了定量描述其宏观力学行为的多尺度力学模型。首先,根据成分的实际尺度特征,对 FRC 各尺度的复合材料模型(包括硬化水泥浆、水泥砂浆和介质 FRC)进行几何重构;其次,利用等效包容理论和 Ottosen 失效准则,建立各尺度复合材料的刚度和强度方程,并从微观结构的刚度和强度上升到 FRC 的宏观力学行为,提出了 FRC 的多尺度力学模型;最后,经 文献中的实验结果验证,利用所提出的模型对 FRC 固化过程中的加载诱导应力响应和宏观力学性能的演变,以及体积分数、长径比和空间取向等钢纤维参数对 FRC 力学性能的影响进行了数值研究。


Mechanics of Materials

Phase-field study of the solutes-interstitial loops interaction in Fe–Cr alloys

Wang Heran, Yu Kang, Wang Jincheng, Wu Lu, Zhang Wen, Zhang Jing

doi:10.1016/j.mechmat.2023.104865

铁铬合金中溶质-间隙环相互作用的相场研究

Interstitial dislocation loops are typically formed in post-irradiated materials, such as Ferritic-Martensitic Fe–Cr alloys. These loops demonstrate solute segregation along their perimeters, effectively pinning the dislocation climb and resulting in high-density, small-sized loops that cause embrittlement. Phase-field simulations were conducted to investigate the behavior of Cr segregation in the stress field of a<100> type and various a/2<111> type interstitial dislocation loops in post-irradiated Fe–10Cr alloy. The study considers the long-range elastic interaction of solute Cr within the stress field of dislocation loops in a cubic elastic anisotropic material. The findings reveal a nonuniform stress distribution along the loop's perimeter depending on the included angle of habit plane normal n and Burgers vector b; the nonuniformity becomes more pronounced as the Burgers vector deviates from the normal direction. Furthermore, this nonuniform stress induces Cr segregation within regions experiencing tensile stress and Cr depletion in compression stress regions. Furthermore, a comprehensive analytical solution has been developed to characterize the diverse stress fields and solute segregation induced by interstitial dislocation loops with varying habit planes and Burgers vectors. The proposed analytical model effectively depicts the stress distribution of various dislocation loops, resulting in a Cr segregation profile that closely approximates those obtained through phase-field simulations. A thorough analysis of solute segregation mechanisms also elucidates the dispersed fine-scale nature and high density observed in experimental investigations of dislocation loops.

铁素体-马氏体铁铬合金等辐照后材料中通常会形成间隙位错环。这些环路沿其周边显示出溶质偏析,有效地固定了位错的攀升,从而形成高密度、小尺寸的环路,导致脆化。我们进行了相场模拟,以研究辐照后 Fe-10Cr 合金中 a<100> 型和各种 a/2<111> 型间隙位错环应力场中的铬偏析行为。该研究考虑了在立方弹性各向异性材料中,溶质铬在差排环应力场中的长程弹性相互作用。研究结果表明,沿着差排环周边的应力分布不均匀,这取决于习性平面法线与布尔格斯矢量 b 的夹角;当布尔格斯矢量偏离法线方向时,这种不均匀性变得更加明显。此外,这种不均匀应力会在承受拉伸应力的区域诱发铬偏析,在压缩应力区域诱发铬损耗。此外,我们还开发了一种全面的分析解决方案,用于描述由具有不同习性平面和布尔矢量的间隙位错环引起的不同应力场和溶质偏析。所提出的分析模型有效地描述了各种位错环的应力分布,从而得出了与相场模拟所得结果非常接近的克拉偏析曲线。对溶质偏析机制的透彻分析还阐明了在差排环实验研究中观察到的分散细尺度性质和高密度。


Thin-Walled Structures

Vibration analysis of FGM anisogrid lattice plates with one width fold based on the continuous model using the GDQE method

Luo Jijun, Peng Shengguang, Hou Suxia, Kiani Yaser

doi:10.1016/j.tws.2023.111386

使用 GDQE 方法对基于连续模型的单宽折叠 FGM anisogrid 格构板进行振动分析

This research tests the idea of folding on the free vibration response of anisogrid lattice plates. It is assumed that the oblique and straight ribs with functionally graded materials (FGMs) construct the lattice plate. The stiffness and mass of the whole plate are computed by employing the global continuous model based on the shear deformable orthotropic plates. Then a width fold is created in the plate to check its effect on improving the system's natural frequencies. An element-based 2D generalized differential quadrature method recently developed solves this problem. This method divides the physical domain into simple domains (patching) and distributes a series of nodes on each patch (quadrature scheme). The motion equations of each patch are derived using Hamilton's principle. Next, the displacement and stress resultant continuity conditions are satisfied between common nodes. After that, the obtained global equations are solved, and the natural frequencies of such structures are calculated. After validating the response with the available literature, the influence of composite characteristics and geometry on the folded FGM lattice plate is distinguished.

本研究测试了折叠对等栅格板自由振动响应的影响。假定斜肋和直肋由功能分级材料(FGM)构成格构板。通过采用基于剪切变形正交板的全局连续模型,计算整个板的刚度和质量。然后在板上创建宽度折叠,以检查其对改善系统固有频率的影响。最近开发的一种基于元素的二维广义微分正交方法解决了这一问题。该方法将物理域划分为多个简单域(补丁),并在每个补丁上分布一系列节点(正交方案)。利用汉密尔顿原理推导出每个补丁的运动方程。然后,在公共节点之间满足位移和应力结果连续性条件。之后,求解得到的全局方程,并计算出这种结构的固有频率。在根据现有文献对响应进行验证后,区分了复合材料特性和几何形状对折叠式 FGM 晶格板的影响。


Behaviour and design of high strength steel circular hollow section member under pure torsion

Devi Soibam Monika, Devi Sanasam Vipej, Singh Tekcham Gishan

doi:10.1016/j.tws.2023.111387

高强度钢圆形空心截面构件在纯扭力作用下的行为和设计

The paper presents a detailed numerical investigation on the performance of high strength steel (HSS) circular hollow section (CHS) member subjected to pure torsion. Three grades of HSS, viz., S700, S900 and S1100, were considered in the study. Finite element (FE) models were initially developed and validated against the available test results. Further, the validated FE models were used for parametric study. Cross-sections of varying thickness and diameters, as well as HSS grades, were considered for the parametric study. The results generated from the parametric study were then utilised to assess the effect of steel grades on the torsional capacities and deformed shapes at ultimate and post-ultimate capacities. The effect of ratio of yield strength to ultimate ratio on the normalised member capacities has also been studied. Furthermore, the applicability of existing design equations for members subjected to pure torsion have been assessed against the FE generated member capacities. Based on the analysis, most of design predictions outlined in European and American Standards, as well as those proposed by various researchers were found unsuitable for design of HSS CHS under torsion. Hence, two modified design equations based on continuous strength method and direct strength method has been proposed. The modified design methods were found to predict more accurate and reliable torsional capacities.

本文对高强度钢(HSS)圆形空心截面(CHS)构件在纯扭力作用下的性能进行了详细的数值研究。研究中考虑了三种等级的高强度钢,即 S700、S900 和 S1100。最初开发了有限元(FE)模型,并根据现有的测试结果进行了验证。此外,经过验证的有限元模型还被用于参数研究。参数研究考虑了不同厚度和直径的横截面以及不同等级的高速钢。然后利用参数研究得出的结果来评估钢材等级对极限和后极限扭转能力和变形形状的影响。此外,还研究了屈服强度与极限比率对归一化构件承载力的影响。此外,还根据 FE 生成的构件承载力评估了现有的纯扭转构件设计方程式的适用性。根据分析结果,发现欧洲和美国标准中概述的大多数设计预测以及不同研究人员提出的设计预测都不适合在扭转情况下设计 HSS CHS。因此,我们提出了基于连续强度法和直接强度法的两种修正设计公式。结果发现,修改后的设计方法能预测更准确、更可靠的抗扭能力。




来源:复合材料力学仿真Composites FEM
ACTMechanicalSystemDeform振动复合材料UG理论材料多尺度
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:2024-11-03
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】2023年11月21日复合材料SCI期刊最新文章

今日更新:Composites Part A: Applied Science and Manufacturing 3 篇,Composites Science and Technology 2 篇Composites Part A: Applied Science and ManufacturingEnhancing mechanical properties and thermal conductivity in polymer bonded explosives by multi-scale surface modification of carbon fibersHe Guansong, Wang Peng, Zhong Ruolei, Li Xin, Yin Huamo, Chen Jie, Liu Shijun, Yang Zhijiandoi:10.1016/j.compositesa.2023.107918通过对碳纤维进行多尺度表面改性,提高聚合物粘合炸药的机械性能和导热性能Poor interfacial interaction and strength largely restrict the overall performance and practical application of carbon fibers (CFs) reinforced composites. The favorable interfacial properties were the key to realize superior mechanical properties in composites. Herein, we reported a novel multi-scale surface modification strategy of CFs to strengthen interfacial properties. Based on chemical oxidation treatment, the surface of CFs was further in situ grafted by a crosslinked high-strength polymer network consisting of aromatic diisocyanate, graphene oxide (GO) and polyethylenen glycol (PEG), which significantly improved the interfacial bonding and mechanical strength of interface layer itself. Benefitting from this multi-scale surface treatment, a high-efficiency mechanical enhancement of polymer bonded explosives (PBX) was achieved. With only 0.3 wt% fiber content, the maximum tensile and compressive strength PBX composites were both significantly improved, which were 63% and 39% higher than those of pure PBX, respectively. Meanwhile, the thermal conductivity was also enhanced, yielding a significant synergistic enhancement effect. The interface failure mechanism of the composite under stress was clarified by the fracture morphology characterization. This study sheds a light for exploring novel surface modification and has the potential application in in high performance polymer composites.界面相互作用和强度差在很大程度上限制了碳纤维(CFs)增强复合材料的整体性能和实际应用。良好的界面性能是实现复合材料优异机械性能的关键。在此,我们报告了一种新型的多尺度碳纤维表面改性策略,以增强界面性能。在化学氧化处理的基础上,进一步在 CF 表面原位接枝由芳香族二异氰酸酯、氧化石墨烯(GO)和聚乙二醇(PEG)组成的交联高强度聚合物网络,从而显著提高了界面层本身的界面结合力和机械强度。得益于这种多尺度表面处理,实现了聚合物结合炸药(PBX)的高效机械增强。在纤维含量仅为 0.3 wt% 的情况下,PBX 复合材料的最大拉伸强度和抗压强度都得到了显著提高,分别比纯 PBX 复合材料高出 63% 和 39%。同时,热导率也得到了提高,产生了明显的协同增强效应。通过断口形貌表征,阐明了复合材料在应力作用下的界面失效机理。这项研究为探索新型表面改性提供了启示,具有在高性能聚合物复合材料中应用的潜力。Shape-memory polyurethane elastomer originated from waste PET plastic and their composites with carbon nanotube for sensitive and stretchable strain sensorZhou Xing, Wang Guosheng, Li Dexiang, Wang Qi, Zhu Keming, Hao Yaya, Xu Yueyang, Li Nengdoi:10.1016/j.compositesa.2023.107920 利用废 PET 塑料制成的形状记忆聚氨酯弹性体及其与碳纳米管的复合材料,用于灵敏且可拉伸的应变传感器Chemical recycling of polyethylene terephthalate (PET) bottles is prospective for reducing waste plastics. The transformation of waste PET into valuable composites in high efficiency still remains a formidable challenge. Here we report the synthesis of polyurethane elastomer (PUE) by using the degraded products from waste PET via one-pot chain extended process. Then, the composites composed of PUE as substrate with carbon nanotubes as fillers are applied in fabricating stretchable strain sensor. The results show that the degraded product was successfully introduced into the polyurethane chains. The PUE chains showed disordered stacking as the degraded product content increased, with the modulus and elongation at break were up to 763.9 %. The composites assembled strain sensors exhibited stable sensing performance and excellent durability after 1000 cycles at 20 % tensile strain. This may supply a path to efficiently recycle waste PET plastic into valuable and functional composites, and even devices.聚对苯二甲酸乙二酯(PET)瓶的化学回收利用在减少废塑料方面前景广阔。如何高效地将废弃 PET 转变为有价值的复合材料仍是一项艰巨的挑战。在此,我们报告了利用废弃 PET 的降解产物,通过一锅扩链工艺合成聚氨酯弹性体(PUE)的过程。然后,以聚氨酯弹性体为基材,碳纳米管为填料组成的复合材料被应用于制造可拉伸应变传感器。结果表明,降解产物被成功引入到聚氨酯链中。随着降解产物含量的增加,聚氨酯链出现了无序堆叠,模量和断裂伸长率高达 763.9%。组装应变传感器的复合材料在 20% 拉伸应变条件下循环使用 1000 次后,显示出稳定的传感性能和出色的耐用性。这为将废弃 PET 塑料有效回收利用为有价值的功能性复合材料甚至设备提供了一条途径。The simultaneously achieved high permittivity and low loss in tri-layer composites via introducing negative permittivity layerSong Xiaoting, Zhang Zidong, Fan Guohua, Liu Yao, Fan Runhuadoi:10.1016/j.compositesa.2023.107921通过引入负介电常数层,在三层复合材料中同时实现高介电常数和低损耗Dielectric composites with excellent power densities have garnered significant attentions in electrical systems and pulsed energy storage. However, the low permittivity and high dielectric loss are greatly limit their applications. Herein, we present a novel approach involving tri-layer composites, where a middle negative-έ layer is sandwiched between outer positive-έ layers. This design aims to realize the balance of comprehensive performances by the interfacial polarization and synergistic effect between positive and negative-έ layers. Amazingly, the composite with content 3-5-3 with the thickness ratio of 1:20:1 shows remarkable permittivity of 679 coupled with a low loss tangent of 0.017 @ 10kHz, which is approximately 141 times higher than PI matrix with 4.8 of permittivity. Remarkably, the composite with content 3-5-3 (1:1:1) exhibited an improved Ud and high η of 1.35 J/cm3 and 94.5%, respectively. This work presents a new class of tri-layer composites with negative-έ layer, whose design method is applicable in high-property dielectric composites.具有出色功率密度的介电复合材料在电气系统和脉冲储能领域备受关注。然而,低介电常数和高介电损耗极大地限制了它们的应用。在此,我们提出了一种涉及三层复合材料的新方法,即在外层正έ层之间夹入中间负έ层。这种设计旨在通过界面极化和正负έ层之间的协同效应实现综合性能的平衡。令人惊奇的是,厚度比为 1:20:1 且含量为 3-5-3 的复合材料显示出 679 的显著介电常数和 0.017 @ 10kHz 的低损耗正切,这比介电常数为 4.8 的 PI 基体高出约 141 倍。值得注意的是,3-5-3(1:1:1)含量的复合材料显示出更高的 Ud 值和更高的η 值,分别为 1.35 J/cm3 和 94.5%。这项研究提出了一种新型负έ层三层复合材料,其设计方法适用于高特性介电复合材料。Composites Science and TechnologyInterfacial reinforcement of carbon fiber composites through a chlorinated aramid nanofiber interphaseMamolo Steven U., Sodano Henry A.doi:10.1016/j.compscitech.2023.110351 通过氯化芳纶纳米纤维间相实现碳纤维复合材料的界面加固Carbon fiber-reinforced polymers (CFRPs) rely on a strong interfacial bond between the reinforcing fibers and polymeric matrix to yield the high strength and toughness expected by a composite material. Poor interfacial strength leads to sub-optimal load transfer and introduces stress concentrations, which can reduce overall performance and result in catastrophic failure. Aramid nanofibers (ANFs) have shown significant promise for interfacial reinforcement in polymeric composite systems due to their high tensile strength, large specific surface area, and abundant polar functional groups. However, due to the chemically inert nature of carbon fibers, ANFs do not readily bond to their surface – thus limiting their application to CFRPs. In this work, we demonstrate that chlorination of ANFs and oxygen plasma treatment of carbon fibers enables the formation of a chlorinated ANF (Cl-ANF) interphase through chemical and physical adsorption using a simple dip-coating process, while fully preserving the tensile strength of the carbon fibers. The Cl-ANF interphase yielded a 79.8 % increase in interfacial shear strength and a 33.7 % increase in short beam strength. By enhancing the interfacial bond between fiber and matrix without degradation of the fiber&#39;s tensile strength, this method provides a rapid and reliable process to improve the mechanical properties of CFRP composites.碳纤维增强聚合物(CFRP)依靠增强纤维与聚合物基体之间牢固的界面结合力来实现复合材料所期望的高强度和韧性。界面强度差会导致载荷传递效果不理想,并引起应力集中,从而降低整体性能并导致灾难性故障。芳纶纳米纤维(ANFs)具有拉伸强度高、比表面积大和极性官能团丰富等特点,因此在聚合物复合材料体系中的界面加固方面大有可为。然而,由于碳纤维的化学惰性,ANFs 不易与碳纤维表面结合,因此限制了其在 CFRP 中的应用。在这项工作中,我们证明了对 ANFs 进行氯化处理和对碳纤维进行氧等离子体处理后,可通过简单的浸涂工艺,利用化学和物理吸附作用形成氯化 ANF(Cl-ANF)相,同时完全保持碳纤维的抗拉强度。Cl-ANF 中间相使界面剪切强度提高了 79.8%,短束强度提高了 33.7%。通过增强纤维与基体之间的界面结合力而不降低纤维的抗拉强度,这种方法为提高 CFRP 复合材料的机械性能提供了一种快速可靠的工艺。Optimizing energy storage density of the multi–layer composite of poly(vinylidene fluoride) and nano–Ni plated CaCu3Ti4O12 with an ultralow filling contentGao Liang, Zhang Yuting, Xiao Qianqian, Gao Zhengwu, Wang Xuandoi:10.1016/j.compscitech.2023.110353 优化超低填充物含量的聚偏氟乙烯和纳米镍镀层 CaCu3Ti4O12 多层复合材料的储能密度Surface modification of nanoceramics with high dielectric constant can increase dielectric constant of polymer composites voiding excessive dielectric loss, however, low discharged energy density (Ud) of composites at a low loading limits potential applications in high–energy–storage devices under low electric field. Herein, Ni–plated CaCu3Ti4O12 nanoparticle (CCTO@Ni) is used to improve the electric properties of the poly(vinylidene fluoride) monolayer composites (C/PVDF), and an ultralow loading of 0.5 vol% promotes the largest Ud of 2.53 J/cm3 at 230 MV/m, resulting from MWS interface polarization and Coulomb barrier effect included by CCTO@Ni fillers, which is used to further prepare three kinds of multi–layer structured C/PVDF composites by solution casting layer by layer. Comprehensive testing shows that the PVDF–C/PVDF–PVDF–C/PVDF–PVDF five–layer film (P–C–P–C–P) enhances the dielectric constant and breakdown strength to contribute the maximal Ud of 6.65 J/cm3 at 297.8 MV/m, which is 118% larger than that of pure PVDF. Above excellent characteristics are attributed to the interface polarization of the middle C/PVDF layer and the alleviating and blocking effect of the middle and outer PVDF layers, which are clarified in depth by the finite element simulation and enhanced breakdown model.对具有高介电常数的纳米陶瓷进行表面改性可以提高聚合物复合材料的介电常数,从而避免过多的介电损耗,然而,复合材料在低负载时的低放电能量密度(Ud)限制了其在低电场下高能量存储设备中的潜在应用。在本文中,镀镍的 CaCu3Ti4O12 纳米粒子(CCTO@Ni)被用来改善聚偏氟乙烯单层复合材料(C/PVDF)的电性能,0.5 vol% 的超低负载可使其在 230 MV 下的最大放电能量密度达到 2.53 J/cm3。 CCTO@Ni 填料在 230 MV/m 时产生的 MWS 界面极化和库仑势垒效应,进一步通过逐层溶液浇注制备了三种多层结构的 C/PVDF 复合材料。综合测试结果表明,PVDF-C/PVDF-PVDF-C/PVDF-PVDF 五层薄膜(P-C-P-C-P)提高了介电常数和击穿强度,在 297.8 MV/m 时的最大 Ud 为 6.65 J/cm3,比纯 PVDF 大 118%。上述优异特性归功于中间 C/PVDF 层的界面极化以及中间和外层 PVDF 层的缓解和阻挡作用,有限元模拟和增强击穿模型深入阐明了这一点。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