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【新文速递】2023年10月21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 2 篇,Journal of the Mechanics and Physics of Solids 3 篇,Mechanics of Materials 1 篇,Thin-Walled Structures 1 篇

International Journal of Solids and Structures

Inverse identification of plastic anisotropy through multiple non-conventional mechanical experiments

Zhang Y., Yamanaka A., Cooreman S., Kuwabara T., Coppieters S.

doi:10.1016/j.ijsolstr.2023.112534

通过多个非常规力学实验反向识别塑性各向异性

In theory, a single non-conventional mechanical experiment generating inhomogeneous strain fields enables to inversely identify an anisotropic yield function. However, several studies have shown that it is challenging to design such a sufficiently data-rich experiment, particularly when it must be conducted on a standard uniaxial tensile machine. Instead of relying on a single non-conventional uniaxial tensile experiment, combining multiple non-conventional experiments is proposed to inversely identify an advanced anisotropic yield function. The feasibility of the proposed method is verified through the inverse identification of the Yld2000-2d yield function using synthetically generated Digital Image Correlation (DIC) data. This approach accounts for the metrological aspects of DIC while avoiding potential experimental errors and uncertainties related to the selected material model. It has been demonstrated that when a single unconventional tensile test is combined with a non-conventional biaxial tensile test, the inversely identified anisotropy parameters are in good agreement with those found through the conventional method. This finding is contingent on maintaining an equal contribution of the strain states from each experiment to the cost function. Excluding overlapping data points and assigning proper weights to the trustworthy data based on the strain state and the level of plastic deformation is found to be key. The numerical results are experimentally validated, thereby revealing the crucial role of the adopted anisotropic yield function. Furthermore, the uncertainty associated with the inversely identified parameters based on three repetitions of the same experiment is discussed.

从理论上讲,产生不均匀应变场的单一非常规机械实验可以反向确定各向异性屈服函数。然而,多项研究表明,设计这样一个数据量足够丰富的实验具有挑战性,尤其是当实验必须在标准单轴拉伸机上进行时。与依赖单一的非常规单轴拉伸实验不同,我们建议结合多个非常规实验来反向识别先进的各向异性屈服函数。通过使用合成生成的数字图像相关(DIC)数据反向识别 Yld2000-2d 屈服函数,验证了所提方法的可行性。这种方法既考虑到了 DIC 的计量方面,又避免了与所选材料模型相关的潜在实验误差和不确定性。结果表明,当单一非常规拉伸试验与非常规双轴拉伸试验相结合时,反向确定的各向异性参数与通过传统方法发现的参数非常一致。这一发现取决于每次试验的应变状态对成本函数的贡献是否相等。排除重叠数据点,并根据应变状态和塑性变形程度为可信数据分配适当权重是关键所在。实验验证了数值结果,从而揭示了所采用的各向异性屈服函数的关键作用。此外,还讨论了基于三次重复相同实验的反向识别参数的不确定性。


A Modified Buckling Analysis of Slender Pretwisted Bars

Ramaswamy Martin, Stolarska Magdalena A., Stolarski Henryk K.

doi:10.1016/j.ijsolstr.2023.112537

细长预绞杆的修正屈曲分析

Some seventy years ago the so-called “helical fiber model” was proposed to address existing discrepancies between experimental observations and theoretical predictions for pretwisted bars. The discrepancies concerned effects the pretwist had on bending and torsional behavior of such bars, but the same model was later used to show that the previously used theory is also likely to provide unconservative (thus unsafe) estimates of their buckling loads. In spite of the theoretical and practical significance of that finding the “helical fiber model” was deemed too approximate, intuitive and, ultimately, it seems to have been abandoned. As far as buckling is concerned, all publications of the last several decades appear to be based on the original theory that was earlier shown to possibly significantly overestimate the buckling load for pretwisted bars. Thus, in this work the problem of pretwisted bars’ buckling is revisited. As most formulations of the problem, the proposed approach is approximate but, as much as possible, it is justified using established principles of mechanics. In particular, two-field Hellinger-Reissner mixed method is used to define axial and bending stiffness of pretwisted bars, with special attention paid to the definition of the stress field. Although the developments presented in this work follow a different path, the main features of the final model are similar to those of the “helical fiber model” introduced much earlier. However, the proposed formulation affords some additional flexibility in the way it may be used. Numerical examples are presented to illustrate effects of the discussed developments.

大约七十年前,人们提出了所谓的 "螺旋纤维模型",以解决预扭曲钢筋的实验观察和理论预测之间存在的差异。这些差异涉及预扭曲对此类钢筋弯曲和扭转行为的影响,但后来人们使用同一模型表明,以前使用的理论也可能对钢筋的屈曲载荷做出了不保守(因而不安全)的估计。尽管这一发现具有理论和实践意义,但 "螺旋纤维模型 "被认为过于近似和直观,最终似乎被放弃了。就屈曲而言,过去几十年的所有出版物似乎都是基于最初的理论,而该理论早先被证明可能大大高估了预扭钢筋的屈曲载荷。因此,本研究重新探讨了预扭曲钢筋的屈曲问题。与大多数问题的表述一样,所提出的方法是近似的,但尽可能使用既定的力学原理来证明其合理性。特别是采用了两场海灵格-赖斯纳混合法来定义预扭曲杆件的轴向和弯曲刚度,并特别关注了应力场的定义。虽然这项工作的发展遵循不同的路径,但最终模型的主要特征与早先引入的 "螺旋纤维模型 "相似。不过,所提出的模型在使用方式上具有一定的灵活性。本文还列举了一些数值示例,以说明所讨论的发展所产生的影响。


Journal of the Mechanics and Physics of Solids

Nonlinear anisotropic viscoelasticity

Sadik Souhayl, Yavari Arash

doi:10.1016/j.jmps.2023.105461

非线性各向异性粘弹性

In this paper, we revisit the mathematical foundations of nonlinear viscoelasticity. We study the underlying geometry of viscoelastic deformations, and in particular, the intermediate configuration. Starting from the direct multiplicative decomposition of the deformation gradient F=FeFv, into elastic and viscous distortions Fe and Fv, respectively, we point out that Fv can be either a material tensor ( Fe is a two-point tensor) or a two-point tensor ( Fe is a spatial tensor). We show that, based on physical grounds, the second choice is unacceptable. It is assumed that the free energy density is the sum of an equilibrium and a non-equilibrium part. The symmetry transformations and their action on the total, elastic, and viscous deformation gradients are carefully discussed. Following a two-potential approach, the governing equations of nonlinear viscoelasticity are derived using the Lagrange-d’Alembert principle. We discuss the constitutive and kinetic equations for compressible and incompressible isotropic, transversely isotropic, orthotropic, and monoclinic viscoelastic solids. We finally semi-analytically study creep and relaxation in three examples of universal deformations.

在本文中,我们重温了非线性粘弹性的数学基础。我们研究了粘弹性变形的基本几何,尤其是中间构型。从变形梯度的直接乘法分解开始F=FeFv, 分别分解为弹性变形和粘性变形Fe和Fv 我们指出Fv可以是材料张量(Fe是两点张量)或两点张量(Fe是空间张量)。我们将证明,根据物理原理,第二种选择是不可接受的。假设自由能密度是平衡和非平衡部分之和。我们仔细讨论了对称变换及其对总变形、弹性变形和粘性变形梯度的作用。按照双势垒方法,利用拉格朗日-达朗贝尔原理推导出非线性粘弹性的支配方程。我们讨论了可压缩和不可压缩各向同性、横向各向同性、正交各向同性和单斜粘弹性固体的构成方程和动力学方程。最后,我们对三个普遍变形实例中的蠕变和松弛进行了半分析研究。


How does roughness kill adhesion?

Afferrante L., Violano G., Dini D.

doi:10.1016/j.jmps.2023.105465

粗糙度如何破坏附着力?

It is well–known that adhesion is strongly influenced by surface roughness. Nevertheless, the literature currently contains an ongoing debate regarding which roughness scales are primarily responsible for adhesion loss. In this study, we aim to contribute to this debate by conducting numerical simulations on self-affine fractal profiles with varying fractal dimensions. Our results reveal that the long-wavelength portion of the roughness spectrum plays a crucial role in killing adhesion when considering profiles with Hurst exponent H > 0 . 5 . Conversely, for profiles with H < 0 . 5 , results show a different trend, indicating that adhesive stickiness is also influenced by short wavelength roughness. These findings are corroborated by our recent experimental observations. In such case, adhesive hysteresis and pull-off force exhibit a continuous decrease with increasing roughness scales. However, for H > 0 . 5 , the pull-off force converges toward a finite value as the magnification increases.

众所周知,附着力受表面粗糙度的影响很大。然而,目前文献中仍在争论哪种粗糙度尺度是造成附着力损失的主要原因。在本研究中,我们对具有不同分形尺寸的自凹凸分形轮廓进行了数值模拟,旨在为这一争论做出贡献。我们的结果表明,在考虑赫斯特指数 H > 0 .5 .相反,对于 H < 0 .5 时,结果显示出不同的趋势,表明粘附性也受到短波长粗糙度的影响。我们最近的实验观察也证实了这些发现。在这种情况下,粘滞性和拉拔力随着粗糙度尺度的增加而持续下降。然而,当 H > 0 .5 时,随着放大倍率的增加,拉脱力会趋近于一个有限值。


Crystal plasticity modeling for the strengthening effect of multilayered copper-graphene nanocomposites

Jeong Juyoung, Voyiadjis George Z.

doi:10.1016/j.jmps.2023.105468

多层铜石墨烯纳米复合材料强化效应的晶体塑性模型

The paper investigates plastic deformation mechanisms in metal-graphene nanocomposite to demonstrate the strengthening effect of materials using a crystal plasticity finite element (CPFE) model, comparing it with published experimental results. Previous experimental research has identified that the two-dimensional shape of graphene, which effectively controls dislocation motion, can significantly enhance the strength of metals. Given the nature of dislocation motions at submicron length scales, nanopillar compression tests were simulated using a physics-based CP model that incorporates surface nucleation and single-arm source dislocation mechanisms. The crystal plasticity models adopt a configuration of nanolayered composites with layers of copper grains and monolayer graphene sandwiched between them, featuring repeat layer spacings of 200 nm, 125 nm, and 70 nm, respectively. This study quantifies the accumulation of dislocations at the graphene interfaces, contributing to the ultra-high strength of the copper-graphene composite. Furthermore, a Hall-Petch-like correlation is established between yield strength and the number of embedded graphene layers.

本文研究了金属-石墨烯纳米复合材料的塑性变形机制,利用晶体塑性有限元(CPFE)模型证明了材料的强化效果,并将其与已发表的实验结果进行了比较。以往的实验研究发现,石墨烯的二维形状可有效控制位错运动,从而显著增强金属的强度。鉴于位错运动在亚微米长度尺度上的性质,我们使用基于物理学的 CP 模型模拟了纳米柱压缩试验,该模型包含了表面成核和单臂源位错机制。晶体塑性模型采用了纳米层状复合材料的结构,铜粒层和单层石墨烯夹在铜粒层和单层石墨烯之间,重复层间距分别为 200 nm、125 nm 和 70 nm。这项研究量化了石墨烯界面上位错的积累,这有助于铜石墨烯复合材料的超高强度。此外,在屈服强度和嵌入石墨烯层的数量之间建立了类似霍尔-佩奇的相关性。


Mechanics of Materials

A two-stage approach for material parameters identification in spark plasma sintering

Kumar A., Bernet M., Deillon L., Afrasiabi M., Bambach M.

doi:10.1016/j.mechmat.2023.104834

火花等离子烧结材料参数识别的两阶段方法

A fully coupled electrical-thermo-mechanical model is essential to an in-depth understanding of the spark plasma sintering (SPS) process, where the mechanical modeling is heavily dependent on the constitutive equations and their material parameters. This paper proposes a two-stage approach that integrates direct experimental measurements with numerical simulations, providing a more comprehensive and reliable basis for identifying the material parameters in SPS. We develop a finite element-based fully coupled process model in COMSOL Multiphysics® and validate it experimentally. The parameter identification procedure achieves an average prediction error below 1.5% when applied to copper and nickel SPS at different heating rates from 25 to 100 K/min. This robust numerical-experimental approach establishes a transferable technique that can be used for other materials commonly used in SPS.

要深入了解火花等离子烧结(SPS)过程,必须建立一个完全耦合的电气-热力学模型,而力学模型在很大程度上取决于构成方程及其材料参数。本文提出了一种将直接实验测量与数值模拟相结合的两阶段方法,为确定 SPS 中的材料参数提供了更全面、更可靠的依据。我们在 COMSOL Multiphysics® 中开发了基于有限元的全耦合过程模型,并对其进行了实验验证。当应用于铜和镍 SPS 时,在 25 至 100 K/min 的不同加热速率下,参数识别过程的平均预测误差低于 1.5%。这种稳健的数值-实验方法建立了一种可移植的技术,可用于 SPS 中常用的其他材料。


Thin-Walled Structures

Protective performance of hybrid triply periodic minimal surface lattice structure

Zhang Yong, Chen Yangang, Li Jixiang, Wu Jiacheng, Qian Liang, Tan Yuanqiang, Li Kunyuan, Zeng Guoyao

doi:10.1016/j.tws.2023.111288

混合三周期最小表面晶格结构的保护性能

A hybrid triply periodic minimal surface (TPMS) method is proposed by the implicit mathematical equation to develop a new TPMS structure. Mechanical properties of the basal TPMS structures and the hybrid TPMS structure subjected to axial crushing load are experimentally and numerically investigated. Results show that the specific energy absorption of hybrid additive and subtractive TPMS structures is up to 97.2% and 82.4% enhancement compared to the basal Schwarz Primitive structure, and the Undulation of load-carrying capacity of hybrid additive and subtractive TPMS structure is 60.1% and 33.3% lower than that of the basal Schoen IWP structure. The effect of topological shape and material distribution on mechanical properties of hybrid TPMS structures are further numerically investigated, and structural factor and wall thickness have significant influence on crashworthiness. Furthermore, the crushing behavior of hybrid additive TPMS and square honeycomb subjected to in-plane and out-of-plane impact loads are investigated, and the hybrid additive TPMS structure shows significant crashworthiness advantage in in-plane crushing condition. Furthermore, the multi-objective optimization is carried out to obtain the optimal crushing performance of the hybrid additive TPMS structure. The hybrid design can provide a good guidance for the research on crashworthiness of the TPMS structures.

通过隐式数学方程提出了一种混合三周期最小面(TPMS)方法,以开发一种新的 TPMS 结构。实验和数值研究了基底 TPMS 结构和混合 TPMS 结构在轴向挤压载荷作用下的力学性能。结果表明,与基体 Schwarz Primitive 结构相比,混合加法和减法 TPMS 结构的比能量吸收分别提高了 97.2% 和 82.4%,混合加法和减法 TPMS 结构的承载能力 Undulation 比基体 Schoen IWP 结构分别降低了 60.1% 和 33.3%。进一步数值研究了拓扑形状和材料分布对混合 TPMS 结构力学性能的影响,发现结构因子和壁厚对耐撞性有显著影响。此外,还研究了混合添加剂 TPMS 结构和方形蜂窝结构在平面内和平面外冲击载荷作用下的挤压行为,结果表明混合添加剂 TPMS 结构在平面内挤压条件下具有显著的耐撞性优势。此外,还进行了多目标优化,以获得混合添加剂 TPMS 结构的最佳挤压性能。该混合设计可为 TPMS 结构的耐撞性研究提供良好的指导。



来源:复合材料力学仿真Composites FEM
ACTMechanicalAdditiveDeformComsol复合材料非线性ECAD理论材料控制试验电气
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【新文速递】2023年10月23日固体力学SCI期刊最新文章

今日更新:International Journal of Solids and Structures 1 篇,Journal of the Mechanics and Physics of Solids 1 篇,Thin-Walled Structures 2 篇International Journal of Solids and StructuresThe peeling behavior of a heterogeneous elastic film on a rigid substrateYin Hanbin, Peng Zhilong, Chen Shaohuadoi:10.1016/j.ijsolstr.2023.112529刚性基底上异质弹性薄膜的剥离行为Although the interfacial peeling behavior of a homogeneous film-substrate system is well understood, the peeling process of a heterogeneous elastic film bonded to a rigid substrate is still unclear. In the present paper, the peeling behavior of a heterogeneous film adhering on a rigid substrate under a vertical peeling force is investigated theoretically, in which the film’s heterogeneity is characterized by the change of bending stiffness along the length of the film. Based on the principle of minimum potential energy, the typical relationship between the peeling force and the peeling displacement during the whole peeling process is achieved. Different from the homogeneous film case, the peeling force can be regulated dramatically by the film’s heterogeneous bending stiffness during the peeling process. When the interfacial debonding front propagates from a compliant segment to a stiff segment, the peeling force is enhanced; while the peeling force is weakened as the interfacial debonding front goes from a stiff segment to a compliant one. The enhancement or weakening of the peeling force depends not only on the bending stiffness of each segment of the film but also on the bending stiffness ratio of neighboring segments, as well as the adhesion length of each segment and the interfacial adhesion properties. The mechanism underlying the heterogeneity-induced tunable peeling force is further elucidated by the change rate of elastic bending energy stored in the film and energy overcoming the interfacial interaction potential during the peeling process. The transfer and redistribution of the elastic bending energy are the main factors that induce the change of peeling force as the interfacial debonding front reaches the boundary of neighboring segments with different bending stiffness. The results of this paper can provide a new strategy for designing film-substrate systems with adjustable adhesion without changing the interfacial characteristics.虽然对同质薄膜-基底系统的界面剥离行为已经有了很好的理解,但对粘附在刚性基底上的异质弹性薄膜的剥离过程仍不清楚。本文从理论上研究了粘附在刚性基底上的异质薄膜在垂直剥离力作用下的剥离行为。根据最小势能原理,得到了整个剥离过程中剥离力与剥离位移之间的典型关系。与均质薄膜的情况不同,在剥离过程中,薄膜的异质弯曲刚度可以极大地调节剥离力。当界面脱粘前沿从顺应段传播到刚性段时,剥离力增强;而当界面脱粘前沿从刚性段传播到顺应段时,剥离力减弱。剥离力的增强或减弱不仅取决于薄膜每个区段的弯曲刚度,还取决于相邻区段的弯曲刚度比,以及每个区段的粘附长度和界面粘附特性。在剥离过程中,储存在薄膜中的弹性弯曲能和克服界面相互作用势能的能量的变化率进一步阐明了异质性诱导的可调剥离力的机理。当界面脱粘前沿到达具有不同弯曲刚度的相邻片段的边界时,弹性弯曲能的转移和再分配是引起剥离力变化的主要因素。本文的研究结果为在不改变界面特性的情况下设计粘附力可调的薄膜-基底系统提供了一种新策略。Journal of the Mechanics and Physics of SolidsComplementing a continuum thermodynamic approach to constitutive modeling with symbolic regressionGarbrecht Karl, Birky Donovan, Lester Brian, Emery John, Hochhalter Jacobdoi:10.1016/j.jmps.2023.105472用符号回归对连续热力学方法进行构型建模的补充An interpretable machine learning method, physics-informed genetic programming-based symbolic regression (P-GPSR), is integrated into a continuum thermodynamic approach to developing constitutive models. The proposed strategy for combining a thermodynamic analysis with P-GPSR is demonstrated by generating a yield function for an idealized material with voids, i.e., the Gurson yield function. First, a thermodynamic-based analysis is used to derive model requirements that are exploited in a custom P-GPSR implementation as fitness criteria or are strongly enforced in the solution. The P-GPSR implementation improved accuracy, generalizability, and training time compared to the same GPSR code without physics-informed fitness criteria. The yield function generated through the P-GPSR framework is in the form of a composite function that describes a class of materials and is characteristically more interpretable than GPSR-derived equations. The physical significance of the input functions learned by P-GPSR within the composite function is acquired from the thermodynamic analysis. Fundamental explanations of why the implemented P-GPSR capabilities improve results over a conventional GPSR algorithm are provided.将一种可解释的机器学习方法--基于物理信息的遗传编程符号回归(P-GPSR)--集成到连续热力学方法中,以开发构成模型。通过生成理想化空隙材料的屈服函数(即 Gurson 屈服函数),展示了将热力学分析与 P-GPSR 结合起来的拟议策略。首先,基于热力学的分析用于推导模型要求,这些要求在定制的 P-GPSR 实现中作为合适度标准加以利用,或在解决方案中强制执行。P-GPSR 实现与没有物理信息适配标准的相同 GPSR 代码相比,提高了准确性、通用性和训练时间。通过 P-GPSR 框架生成的产量函数采用复合函数的形式,描述了一类材料,与 GPSR 衍生方程相比,具有更强的可解释性。P-GPSR 在复合函数中学习的输入函数的物理意义来自热力学分析。本文从根本上解释了为什么 P-GPSR 的实施能力比传统 GPSR 算法的结果更好。Thin-Walled StructuresOrigami embedded honeycomb with three-axial comparable and improved energy absorption performanceWang Zhonggang, Yao Shaocheng, Liu Kai, Wei Kai, Gao Tianyu, Zhao Minquandoi:10.1016/j.tws.2023.111295 具有三轴可比性和更佳能量吸收性能的折纸嵌入式蜂窝结构Origami has been exploited to various marvelous materials to manifest mechanical properties. In this study, inspired by the distinctive deformation modes of kresling-origami with rotation limitation, a design strategy of embedding kresling-origami into conventional honeycomb for improving energy absorption capacity is proposed. According to different embedding approaches, i.e., replacing or adding cell walls, two types of origami-embedded honeycombs are constructed. To investigate the energy absorption properties of proposed origami-embedded honeycombs, 3D-printed specimens are manufactured and tested under quasi-static compression. The experiment results show that proposed origami-embedded honeycomb have higher specific energy absorption and three-axial comparable energy absorption performance relative to conventional ones. It indicates the design strategy of embedding kresling-origami is practical for improving energy absorption capacity of conventional honeycomb and weakening its anisotropy. In addition, the energy absorption performance of origami-embedded honeycombs with different geometrical configurations is investigated through an established and experimentally validated numerical simulation model. Furthermore, the mechanism (i.e., high energy-absorbing deformation modes of kresling-origami under boundary constraints) of embedding design strategy is clarified via comparison analysis between experiments and simulations. This strategy carves out a novel way to optimize the mechanical properties of honeycomb and may inspire new innovations of metamaterials.折纸已被运用到各种神奇的材料中,以体现其机械特性。本研究受克雷林折纸具有旋转限制的独特变形模式的启发,提出了在传统蜂窝中嵌入克雷林折纸以提高能量吸收能力的设计策略。根据不同的嵌入方法,即替换或添加细胞壁,构建了两种类型的折纸嵌入蜂窝。为了研究拟议的纸黏土蜂窝的能量吸收特性,制作了三维打印试样,并在准静态压缩条件下进行了测试。实验结果表明,与传统蜂窝相比,拟议的折纸嵌入蜂窝具有更高的比能量吸收和三轴可比能量吸收性能。这表明嵌入克雷斯林-折纸的设计策略对于提高传统蜂窝的能量吸收能力和削弱其各向异性是切实可行的。此外,还通过建立并经实验验证的数值模拟模型,研究了不同几何构型的折纸嵌入蜂窝的能量吸收性能。此外,通过实验和模拟的对比分析,阐明了嵌入设计策略的机理(即在边界约束条件下克雷斯林-折纸的高能量吸收变形模式)。该策略为优化蜂窝材料的力学性能开辟了一条新途径,并可能为超材料的创新带来启发。A new analytical approach for nonlinear thermo-mechanical postbuckling of FG-GPLRC circular plates and shallow spherical caps stiffened by spiderweb stiffenersNam Vu Hoai, Minh Tran Quang, Hieu Pham Thanh, Hung Vu Tho, Tu Bui Tien, Hoai Nguyen Thi Thanh, Dong Dang Thuydoi:10.1016/j.tws.2023.111296FG-GPLRC 圆板和蛛网加强筋加固的浅球形盖非线性热机械后屈曲的新分析方法For the first time, the problem of nonlinear postbuckling of circular plates and shallow spherical caps reinforced by meridian, parallel stiffeners, and spiderweb stiffeners based on the Donnell shell theory (DST) and von Kármán geometric nonlinearities is presented. The caps/plates and stiffeners are made from functionally graded graphene platelet-reinforced composite (FG-GPLRC). These stiffened structures are subjected to uniformly distributed external pressure or/and uniformly distributed thermal loads and are rested on a nonlinear elastic foundation. By expanding Lekhnitskii&#39;s smeared stiffener technique and employing the Ritz method of energy, the formulas to determine the postbuckling curves of the external pressure–deflection and thermal load-deflection relations of stiffened plates/spherical caps are derived. Meaningful discussions of the various influences of FG-GPLRC stiffeners, material distributions of plate/cap and stiffeners, and geometrical, material, and foundation parameters are shown in the content of the numerical investigations.本文首次提出了基于唐奈壳理论(DST)和 von Kármán 几何非线性的圆板和由经线、平行加劲件和蛛网加劲件加固的浅球形帽的非线性后屈曲问题。盖/板和加强筋由功能分级石墨烯血小板增强复合材料(FG-GPLRC)制成。这些加劲结构承受均匀分布的外部压力或/和均匀分布的热负荷,并固定在非线性弹性基础上。通过扩展 Lekhnitskii 的涂抹加劲技术并采用里兹能量法,得出了加劲板/球形盖外部压力-挠度和热负荷-挠度关系的后屈曲曲线公式。在数值研究内容中,对 FG-GPLRC 加劲件、板/帽和加劲件的材料分布以及几何、材料和地基参数的各种影响进行了有意义的讨论。来源:复合材料力学仿真Composites FEM

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