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【新文速递】2024年7月11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,Journal of the Mechanics and Physics of Solids 2 篇,Thin-Walled Structures 2 篇

International Journal of Solids and Structures

Crack layer modeling of butt-fusion joints induced slow crack growth in high-density polyethylene pipes

Abdulla Almomani, Abdel-Hamid I. Mourad

doi:10.1016/j.ijsolstr.2024.112970

高密度聚乙烯管道中对接熔接接头诱导缓慢裂纹增长的裂纹层建模

The design and reliability of high-density polyethylene (HDPE) pipes can be dictated by the damage tolerance of their butt-fusion joints. A slow crack growth (SCG) model based on the crack layer theory for HDPE pipes internal and external circumferential and butt-fusion joints cracks is developed to investigate the discontinuous SCG behavior and lifetime tf variations. Using the developed model, the discontinuous SCG patterns, jump lengths and lifetime tf can be accurately simulated. In addition, the effects of pipes standard dimension ratio, internal pressure, and temperature on the SCG behavior and tf are investigated. Compared to pipe cracks, it was found that butt-fusion induced SCG can reduce the pipe tf > 60 %. Unlike longitudinal cracks, tf of external circumferential cracks, were found shorter than the internal ones, mandating an earlier evaluation. The new SCG model shows good accuracy with the experimental results. The same substitute geometry approach used can be followed for othercomplex designs, which aids in establishing a fundamental methodology for more realistic lifetime predictions.

高密度聚乙烯(HDPE)管道的设计和可靠性取决于其对接熔接接头的损伤容限。本文基于裂纹层理论,针对高密度聚乙烯(HDPE)管道内外圆周和对接熔接接头裂纹建立了缓慢裂纹生长(SCG)模型,以研究不连续 SCG 行为和寿命 tf 变化。利用所建立的模型,可以准确模拟不连续 SCG 模式、跳跃长度和寿命 tf。此外,还研究了管道标准尺寸比、内部压力和温度对 SCG 行为和 tf 的影响。研究发现,与管道裂缝相比,对接熔合诱发的 SCG 可使管道的 tf 降低 > 60%。与纵向裂缝不同,外部圆周裂缝的 tf 比内部裂缝短,因此需要更早地进行评估。新的 SCG 模型与实验结果显示出良好的准确性。同样的替代几何方法也可用于其他复杂的设计,这有助于为更真实的寿命预测建立基本方法。


Journal of the Mechanics and Physics of Solids

Imbibition of water into a cellulose foam: the kinetics

Ratul Das, Vikram S. Deshpande, Norman A. Fleck

doi:10.1016/j.jmps.2024.105763

水浸入纤维素泡沫:动力学

Cellulose foams are representative of many porous engineering solids that can absorb a large quantity of fluid such as water. Experiments are reported to give insight into water rise in cellulose foams and the underlying mechanisms. The water rise characteristic of water height h versus time t displays a distinct knee on a log-log plot; this knee separates an initial regime where h scales as t 1/2 from a subsequent regime where h scales as t 1/4. The rate of water rise below the knee is consistent with the Washburn law of water rise in a single dominant capillary, and the knee in the h(t) curve suggests that the Jurin height of this large capillary has been attained. Water rise in the foam above the knee of the h(t) curve is interpreted as water rise in a population of small capillaries with a wide range of radius that feed off the dominant capillary. A series of critical experiments support this interpretation, including water rise in inclined columns, and water rise from a limited reservoir of water. A simple analytical model is used to provide a physical explanation for the observations. Additionally, X-ray computer tomography is used to deduce the probability density function of the small capillaries. The experimental findings are in support of the hypothesis that water rise in the cellulose foam is driven by capillary action and not by diffusion.

纤维素泡沫是许多多孔工程固体的代表,可以吸收大量液体(如水)。本报告通过实验深入探讨了纤维素泡沫中的水上升现象及其内在机理。水高度 h 随时间 t 变化的水上升特性在对数-对数图上显示出一个明显的膝点;该膝点将 h 随 t 1/2 变化的初始状态与 h 随 t 1/4 变化的后续状态区分开来。膝点以下的水位上升速度符合单个主要毛细管中水位上升的沃什伯恩定律,而 h(t)曲线上的膝点表明,该大型毛细管的汝林高度已经达到。h(t) 曲线膝盖以上泡沫中的水上升被解释为从主要毛细管中汲取水的半径范围较大的小毛细管群中的水上升。一系列关键实验支持了这一解释,包括倾斜柱中的水上升和来自有限储水层的水上升。一个简单的分析模型为观测结果提供了物理解释。此外,还利用 X 射线计算机断层扫描来推断小毛细管的概率密度函数。实验结果支持这样的假设,即纤维素泡沫中水的上升是由毛细作用而非扩散驱动的。


Statistical mechanics of plasticity: Elucidating anomalous size-effects and emergent fractional nonlocal continuum behavior

Pratik Khandagale, Liping Liu, Pradeep Sharma

doi:10.1016/j.jmps.2024.105747

塑性统计力学:阐明异常尺寸效应和出现的分数非局部连续行为

Extensive experiments over the decades unequivocally point to a pronounced scale-dependency of plastic deformation in metals. This observation is fairly general, and broadly speaking, strengthening against deformation is observed with the decrease in the size of a relevant geometrical feature of the material, e.g., the thickness of a thin film. The classical theory of plasticity is size-independent, and this has spurred extensive research into an appropriate continuum theory to elucidate the observed side effects. This pursuit has led to the emergence of strain gradient plasticity, along with its numerous variants, as the paradigm of choice. Recognizing the constrained shear of a thin metallic film as the model problem to understand the observed size-effect, all conventional (and reasonable candidate) theories of strain gradient plasticity predict a scaling of yield strength that inversely varies with the film thickness ∼h−1. Experimental findings indicate a considerably diminished scaling, the magnitude of which can exhibit significant variation based on processing conditions or even the mode of deformation. As an example, the scaling exponent as low as −0.2 has been observed for as-deposited copper thin films. Two perspectives have been posited to explain this perplexing anomaly. Kuroda and Needleman (2019) argue that the conventional boundary conditions used in strain gradient plasticity theory are not meaningful for the canonical constrained thin film problem and propose a physically motivated alternative. Dahlberg and Ortiz (2019) contend that the intrinsic differential calculus structure of all strain gradient plasticity theories will invariably lead to the incorrect (or rather inadequate) explanation of the size-scaling. They propose a fractional strain gradient plasticity framework where the derivative fractional order is a material property that correlates with the scaling exponent. In this work, we present an alternative approach that complements the existing explanations. We create a statistical mechanics model for interacting microscopic units that deform and yield with the rules of classical plasticity, and plastic yielding is treated as a phase transition. We coarse-grain the model to precisely elucidate the microscopic interactions that can lead to the emergent size-effects observed experimentally. Specifically, we find that depending on the nature of the long-range microscopic interactions, the emergent coarse-grained theory can be of fractional differential type or alternatively a form of integral nonlocal model. Our theory, therefore, provides a partial (and microscopic) justification for the fractional derivative model and makes clear the precise microscopic interactions that must be operative for a continuum plasticity theory to be a valid phenomenological descriptor for capturing the correct scale dependency.

几十年来的大量实验明确指出,金属的塑性变形具有明显的尺度依赖性。这一观察结果具有相当的普遍性,从广义上讲,随着材料相关几何特征(如薄膜厚度)尺寸的减小,可观察到抗变形能力的增强。塑性的经典理论与尺寸无关,这促使人们广泛研究适当的连续理论,以阐明观察到的副作用。应变梯度塑性及其众多变体就是这种研究的成果。所有传统的(以及合理的候选)应变梯度塑性理论都将金属薄膜的约束剪切作为理解所观察到的尺寸效应的模型问题,并预测屈服强度的比例与薄膜厚度 ∼h-1 成反比变化。实验结果表明,这种缩放比例会大大减小,其大小会因加工条件甚至变形模式的不同而发生显著变化。例如,在沉积铜薄膜中观察到的缩放指数低至-0.2。有两种观点可以解释这种令人困惑的反常现象。Kuroda 和 Needleman(2019 年)认为,应变梯度塑性理论中使用的传统边界条件对典型约束薄膜问题没有意义,并提出了一种物理上的替代方案。Dahlberg 和 Ortiz(2019)认为,所有应变梯度塑性理论的内在微分微积分结构必然会导致对尺寸缩放的不正确(或不充分)解释。他们提出了一种分数应变梯度塑性框架,其中导数分数阶是一种与缩放指数相关的材料属性。在这项工作中,我们提出了另一种补充现有解释的方法。我们为相互作用的微观单元创建了一个统计力学模型,这些微观单元按照经典塑性规则变形和屈服,塑性屈服被视为一种相变。我们对模型进行了粗粒化处理,以精确阐明可导致实验观察到的新兴尺寸效应的微观相互作用。具体来说,我们发现,根据长程微观相互作用的性质,出现的粗粒度理论可以是分数微分类型的,也可以是积分非局部模型的一种形式。因此,我们的理论为分数导数模型提供了部分(和微观)理由,并阐明了连续可塑性理论必须具备的精确微观相互作用,才能成为捕捉正确尺度依赖性的有效现象学描述符。


Thin-Walled Structures

Unified Method for Predicting the Fatigue Life of Pipe–Sphere Joints in Grid Structures

Saicong Guo, Hanchao Liu, Xiaoling Liu, Guoqing Wang, Honggang Lei

doi:10.1016/j.tws.2024.112209

预测网格结构中管球接头疲劳寿命的统一方法

Pipe–sphere joints (PSJs), which are commonly used in grid structures, are susceptible to fatigue failure under cyclic loading caused by suspended cranes. This paper presents a unified method for predicting the fatigue life of PSJs, including the weld toes on both the pipe and sphere surfaces, based on equivalent structural stress. A decomposition and recombination fitting (DRF) method was proposed to determine the optimal functional form of stress concentration factors (SCFs). A nonlinear regression analysis was conducted on the calculated results of 61 common PSJs to obtain a semi-analytical expression for the structural stress of the weld toes. Using this unified method, the fatigue life of the weld toes on both the pipe and sphere surfaces was estimated. The results indicated that the logarithmic ratios between the predicted fatigue life and experimental results were typically 0.93–1.08 for weld toes on pipe surfaces and 0.97–1.13 for weld toes on spherical surfaces, confirming the accuracy of the method. This unified method is applicable to predict the fatigue life of PSJs of various sizes and involves concise mathematical calculations independent of finite element analysis, thereby facilitating engineering applications. The DRF method can be used as a reference for fitting SCFs to specific structures. Furthermore, this prediction method enables the identification of the failure modes in PSJs. As the size of the steel pipe increased, the fatigue failure gradually shifted from the pipe surface to the sphere surface.

网格结构中常用的管球连接(PSJ)在悬挂式起重机引起的循环载荷作用下容易发生疲劳破坏。本文提出了一种基于等效结构应力预测 PSJ 疲劳寿命的统一方法,包括管道和球体表面的焊趾。本文提出了一种分解和重组拟合(DRF)方法,以确定应力集中因子(SCF)的最佳函数形式。对 61 个常见 PSJ 的计算结果进行了非线性回归分析,得到了焊趾结构应力的半解析表达式。利用这种统一方法,估算了管道和球体表面焊趾的疲劳寿命。结果表明,管道表面焊趾的疲劳寿命预测值与实验结果的对数比通常为 0.93-1.08,球体表面焊趾的疲劳寿命预测值与实验结果的对数比通常为 0.97-1.13,证实了该方法的准确性。这种统一的方法适用于预测各种尺寸 PSJ 的疲劳寿命,且数学计算简洁,不需要进行有限元分析,从而方便了工程应用。DRF 方法可作为特定结构拟合 SCF 的参考。此外,这种预测方法还能确定 PSJ 的失效模式。随着钢管尺寸的增大,疲劳破坏逐渐从钢管表面转移到球体表面。


Multi-segmented fifth-order polynomial–shaped shells under hydrostatic pressure

Weeraphan Jiammeepreecha, Komkorn Chaidachatorn, Karun Klaycham, Chainarong Athisakul, Somchai Chucheepsakul

doi:10.1016/j.tws.2024.112214

静水压力下的多段五阶多项式形壳

The design and construction of submerged complex shells for new applications in offshore structures are increasingly popular. Therefore, the purpose of this study is to present the analytical model and Lagrange multipliers associated with the constraint equation for large displacement analysis of a fifth-order polynomial–shaped shell under hydrostatic pressure for the first time. The shell geometry can be computed using differential geometry with a fifth-order polynomial. The energy functional of the fifth-order polynomial–shaped shell is derived based on the principle of virtual work and written in the appropriate form. The nonlinear static responses of the fifth-order polynomial–shaped shell under hydrostatic pressure can be calculated using the nonlinear finite element method via the fifth-order polynomial shape function. This study develops the model using one-dimensional beam elements divided along the shell radius. To avoid the slope of a meridian curve at the equatorial plane approaching infinity, the shell is divided into two regions defined by different surface parameters. At the junction of two adjacent regions, the continuity requirements are established as the constraint conditions using Lagrange multipliers. The numerical results from the proposed methods are demonstrated and discussed, along with the effects of varied seawater depth, thickness, and elastic modulus on the deformed configuration and principal curvature at the deformed state. The results show that the nonlinear displacement is higher than the linear one in the case of the hydrostatic pressure, whereas the case of the internal pressure has an opposite result. For principal curvatures at the apex, the principal curvatures increase as the seawater depth increases, whereas the principal curvatures decrease when the thickness and elastic modulus increase.

水下复杂壳体的设计和建造在近海结构中的新应用日益普及。因此,本研究的目的是首次提出静水压力下五阶多项式形壳大位移分析的分析模型和与约束方程相关的拉格朗日乘数。壳的几何形状可以用五阶多项式的微分几何计算。根据虚功原理推导出了五阶多项式形壳的能量函数,并以适当的形式写出。通过五阶多项式形状函数,可以使用非线性有限元法计算五阶多项式形壳在静水压力下的非线性静态响应。本研究使用沿壳体半径划分的一维梁元素建立模型。为避免赤道面的子午线曲线斜率接近无穷大,壳体被划分为两个由不同表面参数定义的区域。在两个相邻区域的交界处,使用拉格朗日乘法器建立连续性要求作为约束条件。演示和讨论了所提方法的数值结果,以及不同海水深度、厚度和弹性模量对变形构造和变形状态下主曲率的影响。结果表明,在静水压力情况下,非线性位移高于线性位移,而在内部压力情况下,非线性位移则与线性位移相反。就顶点的主曲率而言,主曲率随海水深度的增加而增大,而当厚度和弹性模量增加时,主曲率则减小。



来源:复合材料力学仿真Composites FEM
ACTDeform疲劳非线性UGUMECADLMS裂纹理论材料管道
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首次发布时间:2024-11-21
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【新文速递】2024年7月13日固体力学SCI期刊最新文章

今日更新:Journal of the Mechanics and Physics of Solids 1 篇,Mechanics of Materials 2 篇,Thin-Walled Structures 2 篇Journal of the Mechanics and Physics of SolidsModelling and simulation of growth driven by mechanical and non-mechanical stimuliNatalia M. Castoldi, Peter Pivonka, Luciano Teresi, Vittorio Sansalonedoi:10.1016/j.jmps.2024.105769模拟和模拟由机械和非机械刺 激驱动的增长Living tissues can remarkably adapt to their mechanical and biochemical environments through growth and remodelling mechanisms. Over the years, extensive research has been dedicated to understanding and modelling the complexities of growth. However, the majority of growth laws are based on phenomenological, ad hoc, proposed evolution equations. This work aims to describe a general bulk growth model that developed in the framework of generalised continuum mechanics. This new model of growth is based on a continuum description of the growth process and is an extension of the work of DiCarlo and Quiligotti of the early 2000s. This model builds on the virtual power principle, and the constitutive theory is thermodynamically consistent. The proposed framework allows the inclusion of different constitutive theories linking the elastic strain and stresses, together with accommodating different non-mechanical mechanisms. Moreover, the framework supports anisotropy of both the material and growth, allowing the exploration of complex growth processes further. The descriptive capabilities of the model are demonstrated through numerical benchmarks and simulations describing real-life scenarios, such as the growth of the spine and an artery. The simulation results indicate that the developed thermodynamic consistent growth model is versatile and holds the potential to capture the complexities of living tissue growth, offering valuable insights into biological phenomena and pathologies.生物组织通过生长和重塑机制对其机械和生化环境具有显著的适应性。多年来,广泛的研究致力于理解和模拟增长的复杂性。然而,大多数生长规律是基于现象学的,特别的,提出的进化方程。这项工作旨在描述在广义连续介质力学框架内发展起来的一般体积增长模型。这种新的增长模型是基于对增长过程的连续描述,是DiCarlo和Quiligotti在21世纪初的工作的延伸。该模型建立在虚功率原理的基础上,本构理论在热力学上是一致的。提出的框架允许包含连接弹性应变和应力的不同本构理论,以及适应不同的非机械机制。此外,该框架支持材料和生长的各向异性,允许进一步探索复杂的生长过程。该模型的描述能力通过数值基准和模拟来证明,这些模拟描述了现实生活中的场景,例如脊柱和动脉的生长。模拟结果表明,所开发的热力学一致生长模型是通用的,具有捕获活组织生长复杂性的潜力,为生物现象和病理提供有价值的见解。Mechanics of MaterialsMultifunctional design of lattice metamaterial with desired thermal expansion behaviors using topology optimizationZihao Yang, Yongcun Zhang, Zhangming Wu, Shutian Liudoi:10.1016/j.mechmat.2024.105070基于拓扑优化的具有理想热膨胀行为的晶格超材料多功能设计Designing metamaterials with unprecedented coefficients of thermal expansion (CTEs) is an urgent demand for the majority engineering structures suffering from ambient temperature variation. Current studies on such artificial materials are mainly focused on achieving CTE tunnability through the purposeful design of material microstructure using an intuition based mechanism. In this study, the mechanical properties including maximum bulk modulus, specific stiffness and high thermal conductivity are combined with desired CTEs for designing multifunctional lattice metamaterials through the application of a non-intuitive topology optimization method. Toward this end, the continuous variable of member cross-sectional area is adopted to optimize lattice topology, section sizes of lattice members and material distributions, simultaneously. To meet the manufacturing requirements, an improved member intersection constraint that can cooperate with the present continuous design variable is introduced. A self-programmed routine that can be coupled with any commercial FEA software is developed to implement the present optimization method for the design of lattice metamaterials. Four typical optimization cases corresponding to different practical engineering issues are completed. Compared with the previously reported representative lattice metamaterials that are devised from the intuition or experience of designers, the optimization results obtained in this work demonstrate an obvious superiority in bulk modulus and specific stiffness. Additionally, a bimetallic specimen, fabricated using mechanical processing technology and composed of the metallic constituents Invar and Aluminum alloy, is presented to demonstrate the manufacturability of the optimized lattice microstructures.设计具有前所未有的热膨胀系数(CTEs)的超材料是大多数受环境温度变化影响的工程结构的迫切需求。目前对这类人工材料的研究主要集中在利用基于直觉的机制,通过有目的地设计材料微观结构来实现CTE的可隧穿性。在本研究中,通过应用非直观的拓扑优化方法,将最大体积模量、比刚度和高导热系数等力学性能与所需的cte相结合,设计多功能晶格超材料。为此,采用构件截面面积连续变量,同时优化晶格拓扑结构、晶格构件截面尺寸和材料分布。为了满足制造要求,引入了一种改进的构件相交约束,该约束能与现有的连续设计变量相配合。开发了一个可与任何商业有限元软件耦合的自编程程序,以实现目前晶格超材料设计的优化方法。针对不同的实际工程问题,完成了四个典型的优化案例。与以往报道的根据设计者的直觉或经验设计的具有代表性的点阵超材料相比,本工作获得的优化结果在体积模量和比刚度方面具有明显的优势。此外,利用机械加工技术制备了由金属成分英瓦尔合金和铝合金组成的双金属试样,以证明优化后的点阵微结构的可制造性。Warren truss inspired hierarchical beams for three dimensional hierarchical truss lattice materialsFakhreddin Emami, Andrew J. Grossdoi:10.1016/j.mechmat.2024.105088沃伦桁架启发分层梁三维分层桁架晶格材料Networks of beams are a subject of increasing interest to create architected materials with exceptional mechanical properties and low density. This paper investigates the mechanical properties of one dimensional (1D) hierarchical beams for the development of three dimensional (3D) truss lattice materials. These 1D hierarchical beams are constructed in two configurations by placing axial and inclined struts in single and double laced Warren truss patterns in each side of a beam with polygon cross section. Analytical and numerical analyses have been used to characterize their mechanical properties, including the elastic modulus, second moment of area, and shear stiffness of hierarchical beams drawn from a broad design space. Also, the failure limits of the beams with respect to parent material failure and various buckling modes are probed. Finally, the hierarchical beams have been implemented as the constituent members of Kelvin and octet lattices, and the elastic modulus and failure boundaries of the second-order hierarchical lattices are evaluated. The investigation reveals the competition between the elastic properties in the individual hierarchical beams based on different combinations of the design variables. The stiffness of the designs under compression and bending is found to be a function of the axial member size and cross sectional shape of the hierarchical beam. On the other hand, the shear stiffness of hierarchical beam designs is a function of the inclined member size and their inclination angle. It is demonstrated that incorporating hierarchy in the Kelvin and octet truss lattices can enhance the load bearing capacity of designs at low relative densities when compared to their hollow counterparts. Also, it is shown that second-order hierarchical stretching and bending-dominated lattices incorporating first-order hierarchical beams, can not only achieve but also surpass the strength and stiffness scaling relations established for first-order lattices. This becomes particularly noteworthy when considering bending-dominated lattices, as the hierarchy can drive their stiffness towards the boundaries, enabling them to outperform their equivalent stretching-dominated rivals.梁网是创造具有特殊机械性能和低密度的建筑材料的一个越来越受关注的主题。本文研究一维分层梁的力学性能,为开发三维桁架晶格材料提供参考。这些一维分层梁在两种配置中构造,通过在具有多边形截面的梁的每一侧放置轴向和斜向的单和双带沃伦桁架模式。分析和数值分析已被用于表征它们的力学性能,包括弹性模量、第二面积矩和剪切刚度,从广泛的设计空间绘制的分层梁。此外,还探讨了梁在母材破坏和各种屈曲模式下的破坏极限。最后,将分层梁实现为开尔文格和八元格的组成单元,并计算了二阶分层格的弹性模量和破坏边界。研究揭示了基于不同设计变量组合的单个分层梁的弹性性能之间的竞争。在压缩和弯曲下设计的刚度是轴向构件尺寸和分层梁截面形状的函数。另一方面,分层梁设计的抗剪刚度是倾斜构件尺寸及其倾角的函数。结果表明,与空心桁架相比,在开尔文桁架和八元桁架晶格中加入层次结构可以提高设计在低相对密度下的承载能力。研究还表明,包含一阶梁的二阶拉伸和弯曲控制格不仅可以达到甚至超过一阶格的强度和刚度标度关系。当考虑弯曲主导的格子时,这一点尤其值得注意,因为层次结构可以将它们的刚度推向边界,从而使它们的性能优于等效的拉伸主导的对手。Thin-Walled StructuresResearch on Innovative Fluid-Driven Pipe-Strut Tensegrity StructureShu Li, Akram Samy, Xingfei Yuan, Yongcan Dong, Zhendong Qiudoi:10.1016/j.tws.2024.112221新型流体驱动管杆张拉整体结构研究As a self-equilibrated system under prestresses, the internal forces and geometric configurations of tensegrity structures are highly related. Consequently, by employing active control units internally, the lengths of structural components can be adjusted, enabling control over the structural shape and facilitating motion and actuation. Fluid actuation, as a common type of driving mechanism, is typically achieved by using external fluid actuators or directly replacing structural components with them. In order to better realize the combination of flexible, efficient and adaptable fluid-driven strategy with lightweight, flexible and adjustable tensegrity structure, this paper proposes an innovative pipe-strut tensegrity structure based on the topology of traditional tensegrity structure. In the proposed structure, conventional cables are replaced by flexible pipes to establish a continuous fluid path This construction concept promotes the flow of fluid within the structure, enabling the proposed structure to deform or move under the influence of the fluid. With structural and hydraulic analyses serving as the theoretical foundation, a simplified computational theory based on fluid-structure interaction is thoroughly investigated to analyze this innovative structure. Two specific examples are presented to demonstrate the feasibility of the novel configuration, validate the accuracy of the proposed calculation theory, and verify the possibility of movement and motion trend of the proposed fluid-driven pipe-strut structure.张拉整体结构作为预应力作用下的自平衡体系,其内力与几何构型密切相关。因此,通过内部采用主动控制单元,可以调整结构部件的长度,从而实现对结构形状的控制,并促进运动和驱动。流体作动作为一种常见的驱动机构,通常采用外部流体作动器或直接用其替换结构部件来实现。为了更好地实现柔性、高效、适应性强的流体驱动策略与轻量化、柔性、可调张拉整体结构的结合,本文在传统张拉整体结构拓扑的基础上,提出了一种创新的管撑张拉整体结构。在所提出的结构中,用柔性管道代替传统的电缆,建立连续的流体路径。这种构造理念促进了结构内部流体的流动,使所提出的结构在流体的影响下变形或移动。以结构和水力分析为理论基础,深入研究了基于流固相互作用的简化计算理论来分析这种创新结构。通过两个具体算例验证了新结构的可行性,验证了所提计算理论的准确性,验证了所提流体驱动管支撑结构运动的可能性和运动趋势。Random and harmonic responses of plain woven carbon fiber reinforced conical-conical shell based on machine learning multiscale modellingQingyang Huang, Lin Wang, Fenfei Hua, Qingquan You, Wenkai He, Honghao Zhou, Jie Gao, Wantong Wu, Xiaoqiang Zhoudoi:10.1016/j.tws.2024.112220基于机器学习多尺度建模的素编织碳纤维增强锥形壳体随机谐响应This study analyses the frequency-response characteristics under non-stationary base random acceleration and harmonic points force excitations of plain woven carbon fiber reinforced polymers (PW-CFRP) conical-conical shells comprehensively. Artificial neural network (ANN) based machine learning multiscale modelling strategy is introduced in the process of predicting the mechanical properties of PW-CFRP. The dataset is generated by randomization, linear fitting and two-step homogenization and then trained to generate an ANN to predict the mechanical properties of PW-CFRP. The governing equations of the conical-conical shell under random acceleration excitation are obtained according to the first order shear deformation theory (FSDT) and Hamilton's principle. After the structure is split along the circumference at the excitation points, the harmonic points force excitations are introduced based on the discontinuity condition between conical segments. Generalized differential quadrature (GDQ) is applied during the solving procedure. After comparison studies focusing on the frequency-response characteristics under two types of excitations, two examples on harmonic and random responses of conical-conical shell and conical-cylindrical shell are carried out separately. In this process, the effects of excitation type, excitation and response points, geometric parameters on the frequency-response characteristics are extensively analyzed, which proves efficiency and accuracy of the ANN based machine learning multiscale modelling strategy and the constructed GDQ based computational strategy.本文全面分析了平纹编织碳纤维增强聚合物(PW-CFRP)锥形-锥形壳体在非平稳基底随机加速度和谐波点力激励下的频率响应特性。在预测PW-CFRP力学性能的过程中,引入了基于人工神经网络的机器学习多尺度建模策略。通过随机化、线性拟合和两步均匀化生成数据集,然后训练生成一个人工神经网络来预测PW-CFRP的力学性能。根据一阶剪切变形理论(FSDT)和哈密顿原理,得到了随机加速度激励下圆锥-圆锥壳的控制方程。结构在激励点沿圆周劈裂后,基于锥形段间的不连续条件引入谐波点力激励。在求解过程中应用了广义微分正交法(GDQ)。在对两种激励下的频率响应特性进行对比研究后,分别对圆锥-圆锥壳和圆锥-圆柱壳的谐波响应和随机响应进行了算例分析。在此过程中,广泛分析了激励类型、激励和响应点、几何参数对频率响应特性的影响,证明了基于人工神经网络的机器学习多尺度建模策略和构建的基于GDQ的计算策略的有效性和准确性。来源:复合材料力学仿真Composites FEM

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