【新文速递】2023年11月25日复合材料SCI期刊最新文章

今日更新：Composite Structures 3 篇，Composites Part A: Applied Science and Manufacturing 2 篇

Composite Structures

Flexural behavior evaluation of a foam core curved sandwich beam

Honglei Xie, Wanjin Li, Hai Fang, Shijiang Zhang, Zhixin Yang, Yuan Fang, Feng Yu

doi:10.1016/j.compstruct.2023.117729

泡沫芯材弯曲夹层梁的挠曲行为评估

In this study, curved sandwich beams (CSBs) with glass fiber-reinforced polymer (GFRP) and polyethylene terephthalate (PET) foam core were initially fabricated. Experiments in three-point bending were then performed to understand the flexural behaviors including failure modes, load-bearing capacities, and load-displacement curves. The effects of various geometrical parameters including facesheets and core thicknesses, two different types of cores, and curvature radius were clarified. It was found that the utilization of PET foam in CSBs resulted in a prevention of core shearing failure and a gradual decrease in load-displacement response. Moreover, the results showed that the ultimate load-bearing capacity and stiffness of the CSBs decreased by 17.7% and 61.8%, with a curvature decreased from 1500 to 300 mm, respectively. An analytical model was performed to accurately estimate the experimental failure modes and load-bearing capacities of CSBs. Failure maps were also developed to investigate the various failure modes caused by different geometric parameters of curved sandwich beams. The failure maps offer valuable guidance for the design of lightweight structures.

在这项研究中，首先制作了采用玻璃纤维增强聚合物（GFRP）和聚对苯二甲酸乙二酯（PET）泡沫芯材的曲面夹层梁（CSB）。然后进行了三点弯曲实验，以了解其弯曲行为，包括破坏模式、承载能力和载荷-位移曲线。实验明确了各种几何参数的影响，包括面片和芯材厚度、两种不同类型的芯材以及曲率半径。研究发现，在 CSB 中使用 PET 泡沫可防止芯材剪切失效，并逐渐降低荷载-位移响应。此外，研究结果表明，当曲率从 1500 毫米减小到 300 毫米时，CSB 的极限承载能力和刚度分别降低了 17.7% 和 61.8%。为准确估算 CSB 的实验失效模式和承载能力，我们建立了一个分析模型。此外，还绘制了失效图，以研究不同几何参数对弯曲夹层梁造成的各种失效模式。失效图为轻质结构的设计提供了宝贵的指导。

Boundary Discontinuous Fourier analysis of clamped isotropic and cross-ply laminated plates via Unified Formulation

RW Laureano, JL Mantari, J Yarasca, AS Oktem, J Monge, Xueqian Zhou

doi:10.1016/j.compstruct.2023.117736

通过统一公式对夹紧的各向同性和交叉层压板进行边界非连续傅里叶分析

This paper presents an analytical solution for the static analysis of plates with clamped boundary conditions prescribed at the edges. The displacement field is expressed via the Carrera Unified Formulation (CUF) where an Equivalent-Single-Layer (ESL) approach is adopted. The governing equations are obtained by employing the principle of virtual displacements (PVD) statement. The main novelty is the use of the boundary-discontinuous Fourier-based approach to provide accurate numerical solutions. From thick to thin isotropic, cross-ply laminated and sandwich plates with different side-to-thickness ratios and stacking sequences are studied. Furthermore, the out-of-plane stresses are calculated via both the constitutive relation and the stress recovery technique. The accuracy of the proposed solution is verified by comparing the numerical results obtained with those from the literature and 3D FEM solutions. The present approach seems capable of handling not just fully clamped conditions but also mixed external conditions, which may include clamped and simply-supported edges. The solution approach provided in this article is unique, hence the proposed results might be useful as a benchmark for validating new plate theories and finite elements.

本文提出了一种分析方法，用于对边缘规定了夹紧边界条件的板材进行静态分析。位移场通过卡雷拉统一公式（CUF）表示，其中采用了等效单层（ESL）方法。通过采用虚拟位移原理 (PVD) 声明，获得了控制方程。主要的新颖之处在于使用基于边界的非连续傅立叶方法来提供精确的数值解。研究了从厚到薄的各向同性、交叉层压板和夹层板，以及不同的侧厚比和堆叠顺序。此外，平面外应力是通过构成关系和应力恢复技术计算得出的。通过将所获得的数值结果与文献和三维有限元求解结果进行比较，验证了所提出解决方案的 准确性。本方法似乎不仅能处理完全夹紧条件，还能处理混合外部条件，其中可能包括夹紧和简支撑边缘。本文提供的求解方法是独一无二的，因此提出的结果可以作为验证新板材理论和有限元的基准。

Multiscale topology optimization of gradient lattice structure based on volume parametric modeling

Long Chen, Junjun Che, Shuxun Liang, Yingjun Wang

doi:10.1016/j.compstruct.2023.117746

基于体积参数建模的梯度晶格结构多尺度拓扑优化

In this study, a volume parametric modeling method of lattice structure is proposed, and an efficient multiscale topology optimization framework is realized based on isogeometric analysis (IGA) to construct the gradient lattice structure. The skeleton model is constructed, which can accurately describe the topology structure and improve data utilization and computational efficiency. Based on the skeleton model, a uniform volume parameter lattice structure with an arbitrary topology of multiple types of unit cells is constructed, which is suitable for IGA. Moreover, multiscale topology optimization based on IGA is realized to construct the gradient lattice structure. The same data model is used in modeling, analysis, and optimization, which can accurately represent the geometric shape without discretization errors. At the same time, the multiscale topology optimization iteration is realized by adjusting the density of control points. The optimized model can be directly analyzed and re-optimized, thus realizing the integrated design of lattice structure modeling, simulation, and optimization. The effectiveness and robustness of the algorithm are verified by several mechanical parts and freeform models. These examples show that the gradient lattice structure has higher strength and better stress distribution than the uniform lattice structure under the same boundary conditions.

本研究提出了网格结构的体积参数化建模方法，并基于等几何分析（IGA）实现了高效的多尺度拓扑优化框架，构建了梯度网格结构。构建的骨架模型可以精确描述拓扑结构，提高数据利用率和计算效率。在骨架模型的基础上，构建了具有多种类型单元格的任意拓扑的均匀体积参数晶格结构，适用于 IGA。此外，还实现了基于 IGA 的多尺度拓扑优化，以构建梯度晶格结构。在建模、分析和优化过程中使用了相同的数据模型，可以准确地表示几何形状，而不会产生离散化误差。同时，通过调整控制点密度实现多尺度拓扑优化迭代。优化后的模型可直接进行分析和再优化，从而实现晶格结构建模、仿真和优化的一体化设计。该算法的有效性和鲁棒性通过几个机械零件和自由曲面模型得到了验证。这些实例表明，在相同的边界条件下，梯度晶格结构比均匀晶格结构具有更高的强度和更好的应力分布。

Composites Part A: Applied Science and Manufacturing

Enhanced thermal conductivity of phase change composites with novel binary graphite networks

Biao Cheng, Huafeng Quan, Yuefeng Zhang, Dong Huang, Tongqi Li, Chong Ye, Xingming Zhou, Zhen Fan, Yafang Zhang, Ting Ouyang, Fei Han, Hongbo Liu, Jinshui Liu

doi:10.1016/j.compositesa.2023.107925

利用新型二元石墨网络增强相变复合材料的导热性能

The thermal conductivity and porous structure of carbon-based networks significantly affect the heat exchange efficiency in phase change composites. However, simultaneously improving its thermal conductivity and controlling the formation of micrometer-scale open pores remains a significant challenge. In this study, a binary graphite network is constructed by both high-thermal-conductivity mesophase-pitch carbon fibers and high-textured pyrolysis carbon through chemical vapor deposition and ultra-high temperature graphitization, then embed paraffin to form high-performance phase change composites. The characteristic hierarchical pore structure in the binary graphite network facilitating the paraffin impregnation and its heat exchange efficiency is greatly improved by showing an optimum thermal conductivity of 144.78 W·m-1·K-1 and a phase change enthalpy of 87.4 J·g-1 at 0.6 g·cm-3 graphite skeleton and 51 wt.% paraffin. The developed phase change composites hold great application potential in thermal control for space optical-mechanical systems and other critical aerospace components.

碳基网络的导热性和多孔结构会对相变复合材料的热交换效率产生重大影响。然而，如何同时提高其热导率和控制微米级开放孔隙的形成仍是一项重大挑战。在本研究中，通过化学气相沉积和超高温石墨化技术，利用高导热介相间距碳纤维和高纹理热解碳构建了二元石墨网络，然后嵌入石蜡形成高性能相变复合材料。在 0.6 g-cm-3 的石墨骨架和 51 wt.% 的石蜡条件下，二元石墨网络中 特有的分层孔隙结构有利于石蜡的浸渍，其热交换效率大大提高，最佳热导率为 144.78 W-m-1-K-1，相变焓为 87.4 J-g-1。所开发的相变复合材料在太空光学机械系统和其他关键航空航天部件的热控制方面具有巨大的应用潜力。

Insight into crack propagation induced by fiber orientations during single grain scratching of SiCf/SiC composites using FEM

Yichuan Ran, Renke Kang, Jiansong Sun, Zhigang Dong, Hao Wang, Yan Bao

doi:10.1016/j.compositesa.2023.107928

 

利用有限元分析深入了解 SiCf/SiC 复合材料单晶划痕过程中纤维取向诱发的裂纹扩展

Due to the multiphase structure and anisotropy of ceramic matrix composites (CMCs), crack propagation is extremely complex during grinding. However, there is no full comprehension of the crack propagation law of CMCs in varying fiber directions, which limits high-quality CMCs machining. Based on experimental and numerical results, the effect of fiber directions on crack propagation of SiCf/SiC composites was analyzed. Results demonstrate that the change in crack propagation path is the primary reason why the removal behavior of CMCs is different from traditional ceramics. For CMCs, the interface is the priority path of crack propagation no matter along any fiber direction. Besides, the fiber orientation determines the propagation paths of radial and subsurface cracks, which affects material removal behavior. Comparing the scratched groove, the groove edge damage is the most severe when scratching along the fiber transverse direction, whereas the scratched groove surface quality is best in the perpendicular direction.

由于陶瓷基复合材料（CMC）的多相结构和各向异性，磨削过程中的裂纹扩展极为复杂。然而，人们对 CMC 在不同纤维方向上的裂纹扩展规律尚不完全了解，从而限制了 CMC 的高质量加工。基于实验和数值结果，分析了纤维方向对 SiCf/SiC 复合材料裂纹扩展的影响。结果表明，裂纹传播路径的变化是 CMCs 的去除行为不同于传统陶瓷的主要原因。对于 CMC 而言，无论沿着哪个纤维方向，界面都是裂纹传播的优先路径。此外，纤维取向决定了径向和表层下裂纹的传播路径，从而影响材料的去除行为。比较划痕沟槽，沿纤维横向划痕时沟槽边缘损伤最严重，而垂直方向划痕时沟槽表面质量最好。