【新文速递】2024年3月18日固体力学SCI期刊最新文章
今日更新:Journal of the Mechanics and Physics of Solids 4 篇,Mechanics of Materials 3 篇,International Journal of Plasticity 1 篇,Thin-Walled Structures 1 篇
Journal of the Mechanics and Physics of Solids
Surface wrinkling of a film coated to a graded substrate
Rui-Cheng Liu, Yang Liu, Alain Goriely
doi:10.1016/j.jmps.2024.105603
涂在分级基底上的薄膜表面起皱
We study the surface wrinkling of a stiff thin elastic film bonded to a compliant graded elastic substrate subject to compressive stress generated either by compression or growth of the bilayer. Our aim is to clarify the influence of the modulus gradient on the onset and surface pattern in this bilayer. Within the framework of finite elasticity, an exact bifurcation condition is obtained using the Stroh formulation and the surface impedance matrix method. Further analytical progress is made by focusing on the case of short wavelength limit for which the Wentzel-Kramers-Brillouin method can be used to resolve the eigenvalue problem of ordinary differential equations with variable coefficients. An explicit bifurcation condition is obtained from which the critical buckling load and the critical wavelength are derived asymptotically. In particular, we consider two distinct situations depending on the ratio β of the shear modulus at the substrate surface to that at infinity. If β is of O ( 1 ) or small, the parameters related to modulus gradient all appear in the higher-order terms and play an insignificant role in the bifurcation. In that case, it is the modulus ratio between the film and substrate surface that governs the onset of surface wrinkling. If, however, β ≫ 1 , the modulus gradient affects the critical condition through leading-order terms. Through our analysis we unravel the influence of different material and geometric parameters, including the modulus gradient, on the bifurcation threshold and the associated wavelength which can be of importance in many biological and technological settings.
我们研究了粘合在顺应性梯度弹性基底上的刚性弹性薄膜在双层层压缩或增长产生的压应力作用下的表面起皱现象。我们的目的是阐明模量梯度对双层膜起皱和表面形态的影响。在有限弹性框架内,利用斯特罗公式和表面阻抗矩阵法获得了精确的分叉条件。通过关注短波长极限的情况,取得了进一步的分析进展,在这种情况下,可以使用 Wentzel-Kramers-Brillouin 方法来解决具有可变系数的常微分方程的特征值问题。我们得到了一个明确的分岔条件,并从中近似地推导出临界屈曲载荷和临界波长。我们特别考虑了两种不同的情况,这取决于基体表面的剪切模量与无穷大处的剪切模量之比 β。如果 β 为 O ( 1 ) 或很小,则与模量梯度有关的参数全部出现在高阶项中,在分岔中起的作用不大。在这种情况下,薄膜与基底表面的模量比决定了表面起皱的发生。然而,如果 β ≫ 1,模量梯度会通过前导阶项影响临界条件。通过分析,我们揭示了不同材料和几何参数(包括模量梯度)对分叉临界值和相关波长的影响,这在许多生物和技术领域都非常重要。
Multiscale Thermodynamics-Informed Neural Networks (MuTINN) towards fast and frugal inelastic computation of woven composite structures
M. El Fallaki Idrissi, F. Praud, F. Meraghni, F. Chinesta, G. Chatzigeorgiou
doi:10.1016/j.jmps.2024.105604
多尺度热力学信息神经网络 (MuTINN):实现编织复合材料结构快速、节俭的非弹性计算
The complex behavior of inelastic woven composites stems primarily from their inherent heterogeneity. Achieving accurate predictions of their linear and nonlinear responses, while considering their microstructures, appears feasible through the application of multi-scale modeling approaches. However, effectively incorporating these methodologies into real-scale applications, particularly within FE2analyses, remains challenging due to the significant computational requirements they entail. To overcome this issue, while considering the scale effects, this study introduces an alternative approach based on Artificial Neural Networks (ANNs) to perform a macroscopic surrogate model of composites. This model, referred to as Multiscale Thermodynamics Informed Neural Networks (MuTINN), is founded on thermodynamic principles and introduces specific quantities of interest that serve as internal state variables at the macroscopic level. This captures efficiently the state and evolution laws governing the history-dependent behavior of these composites while retaining the thermodynamic admissibility and the physical interpretability of their overall responses. Moreover, to facilitate its numerical implementation within a FE code, a Meta-UMat has been developed, streamlining the application of multiscale FE-MuTINN approach for composite structure computations. The prediction capabilities of the proposed approach is demonstrated across the material scales, exemplified through diverse instances of woven composite structures. Theses applications account for anisotropic yarn damage and an elastoplastic polymer matrix behavior. The numerical results and the related comparison with experimental findings and FE computations demonstrate remarkable consistency across a wide range of non-proportional loading paths. This promises a potential solution to alleviate the computational challenges associated with multiscale simulations of large composite structures.
非弹性编织复合材料的复杂行为主要源于其固有的异质性。通过应用多尺度建模方法,在考虑其微观结构的同时,准确预测其线性和非线性响应似乎是可行的。然而,由于需要大量的计算要求,将这些方法有效地融入实际应用中,特别是在 FE2 分析中,仍然具有挑战性。为了克服这一问题,同时考虑到尺度效应,本研究引入了一种基于人工神经网络(ANN)的替代方法,以执行复合材料的宏观替代模型。该模型被称为多尺度热力学信息神经网络(MuTINN),它建立在热力学原理的基础上,并引入了特定的相关量,作为宏观层面的内部状态变量。这样就能有效地捕捉到这些复合材料随历史变化的行为的状态和演化规律,同时保留其整体响应的热力学可接受性和物理可解释性。此外,为了便于在 FE 代码中实现数值计算,还开发了 Meta-UMat,简化了复合材料结构计算中多尺度 FE-MuTINN 方法的应用。通过编织复合材料结构的各种实例,展示了所提出方法的跨材料尺度预测能力。这些应用考虑了各向异性纱线损伤和弹塑性聚合物基体行为。数值结果以及与实验结果和有限元计算的相关比较表明,在广泛的非比例加载路径中,结果具有显著的一致性。这有望成为缓解大型复合材料结构多尺度模拟相关计算挑战的潜在解决方案。
Nonlinear optimization for compact representation of orientation distributions based on generalized spherical harmonics
Russell E. Marki, Marko Knezevic
doi:10.1016/j.jmps.2024.105609
基于广义球面谐波的方位分布紧凑表示的非线性优化
An orientation distribution is a necessary input in any crystal plasticity simulation. The computational time involved in crystal plasticity simulations scales linearly with the number of crystal orientations in the input distributions. Reducing the number of crystal orientations in representing the input orientation distributions quantitatively is a critical and necessary requirement for performing computationally efficient crystal plasticity simulations of deformation processes. A procedure for the compaction of orientation distribution functions (ODFs) relying on a spectral representation using series of generalized spherical harmonics (GSH) basis functions was recently developed. Linear fitting of the spectral representation of an ODF containing a compact set of weighted orientations towards a full-size ODF containing many crystal orientations was in the core of the procedure. This paper advances the compaction procedure by replacing the linear with a nonlinear optimization in Matlab for which a suitably defined error, gradient, and Hessian matrix are derived to allow for more efficient, accurate, and greater compactions. The utility of the new procedure is to allow for not only fitting the weights of a compacted set of orientations but to allow for optimizing equally weighted orientations or a combination of optimizing weights and orientations. The new compaction procedure has been successfully applied to compactions of large ODFs of cubic, hexagonal, and orthorhombic polycrystalline metals. In doing so, the evolution of texture, twinning, and stress-strain are predicted at large plastic strains with compact ODFs to agree with the corresponding full size ODFs using crystal plasticity models. In closing, guidance for effective texture compaction trading off the accuracy and computational gains are provided.
取向分布是任何晶体塑性模拟的必要输入。晶体塑性模拟的计算时间与输入分布中晶体取向的数量成线性关系。减少定量表示输入取向分布的晶体取向数量,是对变形过程进行高效计算的晶体塑性模拟的关键和必要条件。最近开发了一种取向分布函数(ODF)的压实程序,该程序依赖于使用广义球面谐波(GSH)基函数系列的光谱表示法。该程序的核心是将包含一组紧凑加权取向的 ODF 的光谱表示与包含许多晶体取向的全尺寸 ODF 进行线性拟合。本文用 Matlab 中的非线性优化代替了线性拟合,从而推进了压实程序的发展,并为此推导出了适当定义的误差、梯度和 Hessian 矩阵,以实现更高效、更准确和更大的压实。新程序的效用在于不仅可以拟合压实方向集的权重,还可以优化同等权重的方向或优化权重和方向的组合。新的压实程序已成功应用于立方、六方和正方多晶金属的大型 ODF 的压实。在此过程中,利用晶体塑性模型预测了在大塑性应变条件下压实 ODF 的纹理、孪晶和应力应变的演变,结果与相应的全尺寸 ODF 一致。最后,还提供了在精度和计算收益之间进行有效纹理压实的指导。
Coupling between viscoelasticity and soft elasticity in main-chain nematic Liquid Crystal Elastomers
L. Rezaei, G. Scalet, M. Peigney, A. Azoug
doi:10.1016/j.jmps.2024.105612
主链向列液晶弹性体中粘弹性与软弹性之间的耦合
Liquid crystal elastomers (LCEs) are a class of smart elastomers exhibiting unusual mechanical behavior, including large energy dissipation and soft elasticity under uniaxial tensile loading. LCEs are composed of liquid crystal molecules, called mesogens, linked by a network of polymer chains. During deformation, the mesogens orient in the direction of the loading, leading to soft elasticity, which is an increase in strain at constant stress. The combination of mesogen rotation and intrinsic polymer viscoelasticity leads to a nonlinear viscoelastic soft elastic behavior. The aim of this paper is to investigate the coupling between the viscoelastic mechanisms and soft elasticity in main chain LCEs. We propose a rheological model in which the mesogen rotation during deformation is represented by a reversible slider while viscoelastic relaxation mechanisms are modeled as series of Maxwell elements coupled or decoupled with mesogen rotation. Fitting this model to experimental data demonstrate that the coupling between polymer chain viscoelasticity and mesogen rotation is partial, i.e. the long-time relaxation mechanisms are coupled and the short-time relaxation mechanisms are decoupled from mesogen rotation. Furthermore, we show that the viscosity of mesogen rotation is not necessary to properly predict the elastic modulus during the soft elasticity but it is needed to properly predict the initiation of the phenomenon.
液晶弹性体(LCE)是一类智能弹性体,具有不同寻常的机械性能,包括单轴拉伸负载下的大能量耗散和软弹性。LCE 由被称为中间体的液晶分子组成,中间体由聚合物链网络连接。在变形过程中,介质会沿着加载方向定向,从而产生软弹性,即在应力不变的情况下应变增加。介质旋转与聚合物固有粘弹性的结合导致了非线性粘弹性软弹性行为。本文旨在研究主链 LCE 中粘弹性机制与软弹性之间的耦合。我们提出了一种流变学模型,其中变形过程中的介质旋转由可逆滑块表示,而粘弹性松弛机制则由一系列与介质旋转耦合或解耦的麦克斯韦元素来模拟。将该模型与实验数据拟合后证明,聚合物链粘弹性与中原旋转之间的耦合是局部的,即长时间松弛机制与中原旋转耦合,而短时间松弛机制与中原旋转解耦。此外,我们还证明了介质旋转的粘度对于正确预测软弹性过程中的弹性模量并不是必需的,但对于正确预测软弹性现象的开始却是必需的。
Mechanics of Materials
DLP printed 3D gyroid structure: Mechanical response at meso and macro scale
Edoardo Mancini, Mattia Utzeri, Emanuele Farotti, Attilio Lattanzi, Marco Sasso
doi:10.1016/j.mechmat.2024.104970
DLP 打印 3D 陀螺结构:中观和宏观尺度的机械响应
Rapid prototyping (RP) technology enables the fabrication of complex geometries, making lattice structures increasingly popular. Lattice structures, known as cellular materials, have garnered significant attention over the past two decades due to their ability to optimise mass distribution in components. These structures excel in mechanical properties, catering to energy absorption (bending-dominated structures) and structural performance (stretch-dominated structures). In this paper, we investigate the behaviour of stretch-dominated lattice structures using periodic surface models, specifically focusing on sheet-based Gyroid cells, to allow for a more efficient macroscale modelling. We study cells and scaffolds of different sizes, considering various triply periodic minimal surface thicknesses and relative densities ranging from approximately 0.2 to 0.65. We explore load applications in directions different from the unit cell's principal axes and analyse the strain rate effect on both bulk and cellular material. The lattice structures are manufactured using epoxy resin and digital light processing (DLP) technology. In the range of relative density investigated, both in quasi-static and dynamic conditions, a linear trend is observed for Young's modulus and compression yield strength. To extend the quasi-static results to the dynamic regime, we employ a more generalized normalization technique. This approach divides Young's modulus and compression yield strength by the behaviour of the base material at a specific strain rate, facilitating the correlation of mechanical properties across the two loading regimes. Based on experimental findings, we implemented and calibrated a bi-linear material model for describing, in macroscale, triply periodic minimal surface (TPMS) Gyroid structures. The model coefficients are parameterized with respect to relative density. In addition, the presented material law was compared with that proposed by Gibson-Ashby. Furthermore, we evaluated the anisotropy of both the base material and the unit cell. The first one is done by testing the 3D printed samples in directions different from the printing one, the latter by using the Zener factor. The anisotropy evaluation confirmed the isotropic behaviour of the unit cell within the range of relative density and test conditions investigated. Finally, we perform linear elastic 3D macroscopic and mesoscopic model simulations for combined shear-compression tests using the implemented bi-linear material model and the anisotropic stiffness matrix (obtained through the homogeneous formulation) for the macroscale, and the base material for the mesoscopic one. The results demonstrate the suitability of the proposed equivalent material model for studying the TPMS Gyroid structure in the elastic regime, both in quasi-static and dynamic states. This allows for an efficient FE modelling process of complex lattice structures.
快速成型(RP)技术能够制造复杂的几何形状,使晶格结构越来越受欢迎。晶格结构被称为蜂窝材料,在过去的二十年里,由于其能够优化部件的质量分布,因此备受关注。这些结构在机械性能方面表现出色,既能吸收能量(以弯曲为主的结构),又能提高结构性能(以拉伸为主的结构)。在本文中,我们使用周期性表面模型研究了拉伸为主的晶格结构的行为,特别关注基于薄片的 Gyroid 细胞,以便更有效地进行宏观建模。我们研究了不同尺寸的细胞和支架,考虑了各种三重周期性最小表面厚度和从约 0.2 到 0.65 的相对密度。我们探索了不同于单元格主轴方向的载荷应用,并分析了应变率对块体和单元格材料的影响。晶格结构是使用环氧树脂和数字光处理(DLP)技术制造的。在所研究的相对密度范围内,无论是在准静态还是动态条件下,杨氏模量和压缩屈服强度都呈现线性趋势。为了将准静态结果扩展到动态机制,我们采用了一种更通用的归一化技术。这种方法将杨氏模量和压缩屈服强度除以特定应变率下的基体材料行为,从而促进了两种加载状态下机械性能的相关性。根据实验结果,我们实施并校准了一个双线性材料模型,用于描述宏观尺度的三周期最小表面(TPMS)Gyroid 结构。模型系数的参数与相对密度有关。此外,我们还将提出的材料定律与 Gibson-Ashby 提出的定律进行了比较。此外,我们还评估了基体材料和单元格的各向异性。前者是通过测试三维打印样品在与打印方向不同的方向上的各向异性来实现的,后者则是通过齐纳因子来实现的。各向异性评估证实,在所调查的相对密度和测试条件范围内,单元格具有各向同性。最后,我们使用已实施的双线性材料模型和各向异性刚度矩阵(通过均质配方获得)进行了线性弹性三维宏观和中观模型模拟,以进行剪切-压缩组合试验。结果表明,所提出的等效材料模型适用于研究 TPMS Gyroid 结构在弹性状态下的准静态和动态状态。这使得复杂晶格结构的高效 FE 建模过程成为可能。
Elastic properties of honeycombs with spline curve cell walls
Ruoshui Wang, Taekwang Ha, Jyhwen Wang
doi:10.1016/j.mechmat.2024.104975
具有花键曲线细胞壁的蜂巢的弹性特性
In the ideal models, cell walls of honeycomb structures are perfect flat sheets or straight lines (viewed from out-of-plane projection), whereas most of the real honeycomb products contain curved cell walls due to the widely employed manufacturing processes. Moreover, some honeycomb products are made intentionally to have corrugated cell walls for an enhanced out-of-plane stability or an increase of structural stiffness. In the presented study, a relative new modeling method for the nonlinear cell walls of honeycomb structures is used. The method makes use of Bezier spline functions to describe the curved cell walls. Energy method and Castigliano's theorem are used to formulate the force-displacement relationship of a single cell wall, and the homogenized stiffness matrix is derived based on the proper boundary conditions of the cell walls. Analytical and experimental verification shows that the proposed model is very accurate and versatile in predicting the mechanical responses of different honeycomb geometries. Parametric studies are conducted, analytically and numerically, to examine the influence of the spline cell wall geometries on the honeycomb's effective in-plane properties and the out-of-plane stability. The study leads to the recommendation of a cell wall design strategy for maximizing the out-of-plane buckling resistance of honeycomb structures.
在理想模型中,蜂窝结构的蜂窝壁是完美的平板或直线(从平面外投影看),而由于广泛采用的制造工艺,大多数实际蜂窝产品的蜂窝壁都是弯曲的。此外,有些蜂窝产品的蜂窝壁是故意做成波纹状的,以增强平面外稳定性或提高结构刚度。本研究针对蜂窝结构的非线性蜂窝壁采用了一种相对较新的建模方法。该方法利用贝塞尔样条函数来描述弯曲的蜂窝壁。能量法和 Castigliano 定理被用来计算单个蜂窝壁的力-位移关系,并根据蜂窝壁的适当边界条件推导出均质化刚度矩阵。分析和实验验证表明,所提出的模型在预测不同蜂窝几何形状的机械响应方面非常准确且通用。通过分析和数值方法进行了参数研究,以检验花键细胞壁几何形状对蜂窝的有效面内特性和面外稳定性的影响。通过研究,提出了最大限度提高蜂窝结构平面外抗屈曲性能的蜂窝壁设计策略建议。
Failure analysis of unidirectional FRP with fiber clusters under transverse pure shear
Xiaofei Pang, Xun Chen, Shufeng Zhang
doi:10.1016/j.mechmat.2024.104978
带纤维簇的单向玻璃钢在横向纯剪切力作用下的失效分析
In nearly all the failure criteria for the FRP (fiber reinforced plastic), the fundamental strength of the FRP under uniaxial tensile, compressive and pure shear stress were utilized to construct appropriate mathematical function relationship with the multiaxial stress. Among them, the strength of the FRP under transverse pure shear stress was influenced by various factors and could not be directly obtained from tests. In this paper, transverse pure shear failure behavior of FRP was studied using finite element analysis based on RVE models, the RSE and HC algorithm were utilized to generate the FRP with different fiber distribution, mainly refers the different fiber clusters which was commonly experimentally observed. The bilinear cohesive model and extended linear Drucker Prager model were used to characterize the mechanical behavior of the interface and matrix respectively. Then, constraint of periodic boundary condition was applied for the RVE models. Difference on failure fracture behavior of FRP with different fiber distribution were identified and assessed under transverse pure shear stress, while the connection between stress triaxiality and initial damage equivalent plastic strain of the matrix was also altered. On this basis, the distinction of the maximum transverse pure shear stress, the crack resistance strength and the transverse shear strength was thoroughly discussed and identified, which provided a theoretic reference for the failure analysis of the FRP.
几乎所有的 FRP(纤维增强塑料)失效标准都是利用 FRP 在单轴拉伸、压缩和纯剪切应力下的基本强度来构建与多轴应力的适当数学函数关系。其中,玻璃钢在横向纯剪切应力下的强度受多种因素影响,无法通过试验直接获得。本文采用基于 RVE 模型的有限元分析方法研究了玻璃钢的横向纯剪切破坏行为,利用 RSE 和 HC 算法生成了不同纤维分布的玻璃钢,主要指实验中常见的不同纤维簇。双线性内聚模型和扩展线性德鲁克-普拉格模型分别用于表征界面和基体的力学行为。然后,对 RVE 模型应用了周期性边界条件约束。在横向纯剪应力作用下,确定并评估了不同纤维分布的玻璃钢在破坏断裂行为上的差异,同时还改变了应力三轴性与基体初始破坏等效塑性应变之间的联系。在此基础上,深入讨论并确定了最大横向纯剪应力、抗裂强度和横向剪切强度的区别,为玻璃钢的破坏分析提供了理论参考。
International Journal of Plasticity
Dynamic evolution of the T1 phase and its effect on continuous dynamic recrystallization in Al–Cu–Li alloys
Kuizhao Wang, Cunsheng Zhang, Zinan Cheng, Haibin Zhao, Zijie Meng, Liang Chen, Guoqun Zhao
doi:10.1016/j.ijplas.2024.103948
铝-铜-锂合金中 T1 相的动态演变及其对连续动态再结晶的影响
The T1 phase is the highest density and most prominent strengthening effect precipitate in Al–Cu–Li alloys, and it undergoes a complex dynamic evolution during hot deformation, which has significant effects on microstructure development and hot working. This study comprehensively characterizes and analyzes the dynamic evolution of the T1 phase at 400°C/0.01 s−1 and its influence on continuous dynamic recrystallization (CDRX). The results indicate that the T1 phase successively undergoes coarsening, fracture, dissolution, dynamic precipitation, recoarsening, and spheroidization during deformation. A shear-coupled diffusion mechanism is proposed to explain the ultrafast coarsening rate of the T1 phase in early deformation. During the dynamic precipitation of the T1 phase, an anomalous inhomogeneous size and spatial distribution of the T1 phase are observed, and a high number density of fine T1 phases form in the matrix (with a thinner, shorter, and denser size at the dislocation wall). The dynamically precipitated T1 phase is affected by the octahedral slip system during the coarsening process and exhibits a selective ripening phenomenon. The T1 phase formed by aging increases the inhomogeneity of the deformation and induces many substructures intragranularly, decreasing the percentage of CDRX grains but increasing the CDRX potential. Conversely, the dynamically precipitated T1 phase and its evolution accelerate CDRX development by promoting the transformation of LAGBs to HAGBs. In addition, the effects of dynamically evolving precipitates on the dislocations and formation modes of LAGBs at various deformation stages are elucidated. The results can provide valuable insights into the regulation of microstructure, and the development of high-performance Al–Cu–Li alloys, and also offer a theoretical and experimental basis for microstructure modeling.
T1 相是铝-铜-锂合金中密度最高、强化效应最突出的析出物,它在热变形过程中经历了复杂的动态演化,对微观结构的发展和热加工有重大影响。本研究全面描述和分析了 T1 相在 400°C/0.01 s-1 下的动态演化及其对连续动态再结晶(CDRX)的影响。结果表明,T1 相在变形过程中先后经历了粗化、断裂、溶解、动态沉淀、再粗化和球化。提出了一种剪切耦合扩散机制来解释 T1 相在变形早期的超快粗化速率。在 T1 相的动态析出过程中,观察到 T1 相的尺寸和空间分布异常不均匀,在基体中形成了高数量密度的细小 T1 相(在位错壁处尺寸更细、更短、更密集)。动态析出的 T1 相在粗化过程中受到八面体滑移系统的影响,表现出选择性熟化现象。老化形成的 T1 相增加了变形的不均匀性,并在晶粒内诱导出许多亚结构,降低了 CDRX 晶粒的百分比,但增加了 CDRX 电位。相反,动态析出的 T1 相及其演化可促进 LAGB 向 HAGB 的转变,从而加速 CDRX 的发展。此外,还阐明了动态演化的析出物在不同变形阶段对 LAGBs 的位错和形成模式的影响。这些结果可为微观结构的调控和高性能铝-铜-锂合金的开发提供有价值的见解,同时也为微观结构建模提供了理论和实验基础。
Thin-Walled Structures
Close-in blast responses of bowstring fold-line-core sandwich panels
Wenyi Bao, Bei Zhang, Yongjun Wang, Yunze Yang, Ben Wang, Zhengyu Qiu, Haiying Cao, Hualin Fan
doi:10.1016/j.tws.2024.111809
弓弦折线夹芯板的近距离爆炸响应
Buildings, critical facilities, and military transport must maintain structural integrity when subjected to explosions. This research introduces a novel protective structure employing a bowstring design and curved sandwich panels featuring a fold-line-core designed to improve the explosion resistance of thin-walled panels. The dynamic responses and crushing modes of these bowstring fold-line-core sandwich panels were examined. The findings demonstrate that the bowstring fold-line-core sandwich panel effectively harnesses the self-supporting capacity of the bowstring structure alongside the energy absorption capabilities of the fold-line-core, resulting in exceptional anti-explosion performance. When subjected to a detonation of 200 g of TNT at a stand-off distance of 0.6 m, the designed panels exhibit minimal deformation. Moreover, the calculated proportional stand-off distance under corresponding operating conditions amounts to 1.026 kg/m1/3.
建筑物、重要设施和军用运输工具在遭受爆炸时必须保持结构的完整性。本研究介绍了一种新型防护结构,采用弓弦设计和具有折线芯材的弧形夹层板,旨在提高薄壁板的抗爆性能。研究考察了这些弓弦折线夹芯板的动态响应和挤压模式。研究结果表明,弓弦折线芯材夹芯板有效地利用了弓弦结构的自支撑能力和折线芯材的能量吸收能力,从而具有优异的抗爆性能。当在 0.6 米的间距内引爆 200 克 TNT 炸药时,所设计的面板变形极小。此外,在相应的工作条件下,计算得出的离地距离比例为 1.026 千克/米1/3。
