基于高阶变形理论的夹层板的弯曲与振动

考虑面板和夹芯的面内刚度和横向剪切刚度以及抗弯刚度,考虑了高阶剪切变形,根据横向剪应变分布情况给出横向剪切转角的位移函数,基于哈密尔顿原理,推导了基于高阶变形理论、适用于软、硬夹芯情况夹层板的基本方程.作为算例,以四边简支条件下的夹层板的弯曲与振动,在不同的面板与芯层的弹性模量比和厚度比下进行了计算,并与Reissner理论、Hoff理论以及邓宗白基于Reissner理论的修正模型的计算结果进行了对比.与前述理论与方法相比,论文方法考虑因素更为全面,对夹层板的适用范围更为广泛,计算结果更为精确.针对Nastran软件计算夹层板的振动问题,对其适用范围作了简要分析.     

点阵增强型复合材料夹层结构的力学性能实验与分析

采用真空导入成型工艺,制备出在面板与芯材界面上具有创新构型的点阵增强型复合材料夹层结构。对其面板拉伸性能、夹层结构剪切与平压性能进行了实验研究,得出点阵增强型复合材料夹层结构经树脂柱增强后,剪切与平压性能均得以提高的结论。对不同跨高比复合材料夹层结构开展了三点与四点弯曲实验,研究其典型受力破坏形态与机理。基于Eshelby等效夹杂原理,采用Mori-Tanaka方法求解了点阵增强型复合材料夹层结构经树脂柱增强后的剪切性能。利用经典夹层梁理论和非线性有限元模拟方法,预估了试件抗弯刚度与受弯极限承载力,理论分析与实验结果较吻合。     

复合材料四面体点阵夹芯梁的自由振动分析

点阵夹芯结构是一种由上下面板和中间点阵芯子组成的新型轻质多功能结构.由于该结构具有独特的结构形式,其力学特性分析比较复杂.论文将离散的点阵芯子等效为连续均匀材料,研究了复合材料四面体点阵夹芯梁的自由振动特性.考虑面板的弯曲变形和芯子的剪切变形,根据Hamilton变分原理,推导出复合材料点阵夹芯梁的自由振动控制方程.以简支边界条件下的四面体点阵夹芯梁为例,求解出固有频率的理论值,并与有限元结果进行对比,两者吻合较好.讨论了面板铺层顺序、杆件半径、杆件倾斜角度、芯子高度以及梁的长度对夹芯梁固有频率的影响.研究结果对于了解复合材料四面体点阵夹芯梁的频率特性具有一定的指导意义.     

四边简支硬夹芯夹层板的弯曲问题研究

现有的夹层结构理论都是将夹芯视为软夹芯,忽略了其面内应力分量和弯曲刚度.该理论不能满足近年来出现的硬夹芯夹层结构.对此,考虑了以上被忽略的因素,修正了Reissner理论的软夹芯假设,提出了考虑夹芯面内应力分量和弯曲刚度的硬夹芯夹层板基本假设.根据最小势能原理得到了硬夹芯夹层板弯曲的基本方程和边界条件,给出了四边简支硬夹芯夹层板在横向载荷下弯曲的解析解.另外本文还研究了硬夹芯夹层板弯曲问题的有限元法,推导了四节点四边形等参单元的有限元列式,并用MATLAB编程求解了具体算例.     

考虑芯层离散特性的方形蜂窝夹层板自由振动分析

针对方形蜂窝夹层板,考虑其离散的芯层结构形式,在经典夹层板理论的基础上,运用Hamilton变分原理导出了其离散结构形式的运动控制方程.该文以四边简支的方形蜂窝矩形夹层板为例,采用傅立叶级数和伽辽金法求解出夹层板固有频率的半解析解,并与有限元仿真结果进行了比较,两者吻合良好.该文还将夹层板与等质量的实体板固有频率进行了比较,讨论了夹层板芯层薄壁间距、厚度、高度以及面板厚度对其固有频率的影响.计算结果表明,夹层板相对实体板具有很大的刚度;芯层薄壁高度相对其它参数对夹层板固有频率的影响更大.     

基于Zig-Zag变形假定的复合材料夹层板的自由振动

针对复合材料夹层板的实际变形特征，基于Zig-Zag变形假定和Mindlin一阶剪切理论，建立了复合材料夹层板自由振动的有限元模型，在该模型中分别对上、下面板和芯体建立了三个独立坐标系，使三部分的转角独立，为具有厚夹芯和软夹芯的复合材料夹层板的动力分析提供了一种更为准确的有限元模型；在此基础上推导了相应的刚度阵和质量阵，并采用子空间迭代法求解。夹层板的固有频率。通过典型考题证明了本模型的有效性。文中最后还通过参数讨论，研究了具有不同长厚比的复合材料夹层板基频的变化规律。     

四边固支蜂窝夹层板1:3内共振非线性动力学分析

基于经典叠层板理沦和几何大变形理沦,将铝基蜂窝芯层等效为一正交异性层,等效弹性参数由修正后的Gibson公式得出,对四边固支蜂窝夹层板非线性动力学特性进行了分析.考虑横向阻尼的影响,建立了四边固支蜂窝夹层板受横向激振力作用的受迫振动微分方程,通过振型正交化将蜂窝夹层板受迫振动微分方程简化成双模态下的动力学控制方程,利用同伦分析方法对双模态下蜂窝夹层板的动力学控制方程进行研究,得到了1∶3内共振下的幅频特性曲线,研究了不同结构尺寸对动力学特性的影响以及蜂窝夹层板作稳态运动时的稳定性问题.论文得到的结果为蜂窝夹层板的设计和实际应用提供了理论依据和数值参考.     

中间支承对随从力作用下矩形薄板稳定性的影响

研究了切向均布随从力作用下,带有中间线支承的矩形薄板的稳定性问题.建立板的运动微分方程,利用微分求积法得到复特征方程.求解复特征方程,得出线支承板复频率随着随从力的变化关系,以及线支承刚度对板失稳形式和临界值的影响.对随从力作用下中间支承四边固支矩形薄板的计算结果表明:对于四边固支板,当边长比为1时,发现存在一个临界线支承刚度值,当线支承刚度小于该值时,板失稳为颤振失稳,当支承刚度大于该值时,板失稳为屈曲失稳;当边长比为2时,板失稳形式保持为屈曲失稳.     

复合材料夹层板的振动及阻尼分析

本文对复合材料夹层板的动态问题提出了一种新的位移修正模式，该位移模式包括了面板的横向剪切变形及夹芯的剪切变形，以此位移模式进行了有限元分析，给出了形成阻尼矩阵的方法。文中还分析了夹层板的阻尼比ψ与夹芯厚度ｈｃ，夹芯材料的阻尼损耗因子β以及夹芯剪切模量Ｇ之间的关系；算例与实验结果的对比表明：本文提出的计算方法可以给出满意的数值结果。     

轻质金属泡沫夹芯曲板的抗爆炸冲击响应研究

夹芯结构具有高比强度、高比刚度和优异的吸能能力,已经被广泛应用于工程结构用来抵御高强度的爆炸冲击载荷。本文采用有限元数值模拟方法研究了爆炸载荷作用下四边固支夹芯曲板的动力响应。比较了同等质量下夹芯曲板、夹芯平板、实体曲板和实体平板四种结构的抗爆炸冲击性能,讨论了不同曲率和非对称因子对结构动力响应的影响,得到了使得夹芯曲板抗爆炸性能最佳的非对称因子。研究结果表明：夹芯曲板的抗爆炸冲击性能优于等质量的夹芯平板、实体曲板和实体平板结构,增大夹芯曲板的曲率能够提高结构的抗爆炸冲击性能。     

Imperfection sensitivity of pyramidal core sandwich structures

Lightweight metallic truss structures are currently being investigated for use within sandwich panel construction. These new material systems have demonstrated superior mechanical performance and are able to perform additional functions, such as thermal management and energy amelioration. The subject of this paper is an examination of the mechanical response of these structures. In particular, the retention of their stiffness and load capacity in the presence of imperfections is a central consideration, especially if they are to be used for a wide range of structural applications. To address this issue, sandwich panels with pyramidal truss cores have been tested in compression and shear, following the introduction of imperfections. These imperfections take the form of unbound nodes between the core and face sheets—a potential flaw that can occur during the fabrication process of these sandwich panels. Initial testing of small scale samples in compression provided insight into the influence of the number of unbound nodes but more importantly highlighted the impact of the spatial configuration of these imperfect nodes. Large scale samples, where bulk properties are observed and edge effects minimized, have been tested. The stiffness response has been compared with finite element simulations for a variety of unbound node configurations. Results for fully bound cores have also been compared to existing analytical predictions. Experimentally determined collapse strengths are also reported. Due to the influence of the spatial configuration of unbound nodes, upper and lower limits on stiffness and strength have been determined for compression and shear. Results show that pyramidal core sandwich structures are robust under compressive loading. However, the introduction of these imperfections causes rapid degradation of core shear properties.     

Design optimization of truss-cored sandwiches with homogenization

Lightweight metallic sandwich plates comprising periodic truss cores and solid facesheets are optimally designed against minimum weights. Constitutive models of the truss core are developed using homogenization techniques which, together with effective single-layer sandwich approaches, form the basis of a two-dimensional (2D) single-layer sandwich model. The 2D model is employed to simulate the mechanical behaviors of truss-cored sandwich panels having a variety of core topologies. The types of loading considered include bending, transverse shear and in-plane compression. The validities of the 2D model predictions are checked against direct FE simulations on three-dimensional (3D) truss core sandwich structures. Optimizations using the 2D sandwich model are subsequently performed to determine the minimum weights of truss-cored sandwiches subjected to various failure constraints: overall and local buckling, yielding and facesheet wrinkling. The performances of the optimized truss core sandwiches with 4-rod unit cell and solid truss members and pyramidal unit cell with hollow truss members are compared with benchmark lightweight structures such as honeycomb-cored sandwiches, tetrahedral core sandwiches and hat-stiffened single layer plates.     

Thermal buckling analysis of truss-core sandwich plates

Truss-core sandwich plates have received much attention in virtue of the high values of strength-to-weight and stifness-to-weight as well as the great ability of impulseresistance recently. It is necessary to study the stability of sandwich panels under the influence of the thermal load. However, the sandwich plates are such complex threedimensional(3D) systems that direct analytical solutions do not exist, and the finite element method(FEM) cannot represent the relationship between structural parameters and mechanical properties well. In this paper, an equivalent homogeneous continuous plate is idealized by obtaining the efective bending and transverse shear stifness based on the characteristics of periodically distributed unit cells. The first order shear deformation theory for plates is used to derive the stability equation. The buckling temperature of a simply supported sandwich plate is given and verified by the FEM. The efect of related parameters on mechanical properties is investigated. The geometric parameters of the unit cell are optimized to attain the maximum buckling temperature. It is shown that the optimized sandwich plate can improve the resistance to thermal buckling significantly.     

Postbuckling analysis of axially loaded functionally graded cylindrical panels in thermal environments

A postbuckling analysis is presented for a functionally graded cylindrical panel of finite length subjected to axial compression in thermal environments. Material properties are assumed to be temperature dependent, and graded in the thickness direction according to a simple power law distribution in terms of the volume fractions of the constituents. The governing equations of a functionally graded cylindrical panel are based on Reddy’s higher order shear deformation shell theory with a von Kármán–Donnell-type of kinematic nonlinearity and including thermal effects. Two cases of the in-plane boundary conditions are considered. The nonlinear prebuckling deformations and initial geometric imperfections of the panel are both taken into account. A boundary layer theory of shell buckling, which includes the effects of nonlinear prebuckling deformations, large deflections in the postbuckling range, and initial geometric imperfections of the shell, is extended to the case of functionally graded cylindrical panels under axial compression. A singular perturbation technique is employed to determine the buckling loads and postbuckling equilibrium paths. The numerical illustrations concern the postbuckling behavior of axially loaded, perfect and imperfect, functional graded cylindrical panels with two constituent materials and under different sets of thermal environments. The influences played by temperature rise, volume fraction distributions, the character of in-plane boundary conditions, transverse shear deformation, panel geometric parameters, as well as initial geometric imperfections are studied.     

Stress and buckling analysis of a thick-walled micro sandwich panel with a flexible foam core and carbon nanotube reinforced composite(CNTRC) face sheets

In this paper, the stresses and buckling behaviors of a thick-walled micro sandwich panel with a flexible foam core and carbon nanotube reinforced composite(CNTRC) face sheets are considered based on the high-order shear deformation theory(HSDT) and the modified couple stress theory(MCST). The governing equations of equilibrium are obtained based on the total potential energy principle. The effects of various parameters such as the aspect ratio, elastic foundation, temperature changes, and volum...     

Metallic sandwich panels subjected to multiple intense shocks

The mechanical response and fracture of metal sandwich panels subjected to multiple impulsive pressure loads (shocks) were investigated for panels with honeycomb and folded plate core constructions. The structural performance of panels with specific core configurations under multiple impulsive pressure loads is quantified by the maximum transverse deflection of the face sheets and the core crushing strain at mid-span of the panels. A limited set of simulations was carried out to find the optimum core density of a square honeycomb core sandwich panels under two shocks. The panels with a relative core density of 4%–5% are shown to have minimum face sheet deflection for the loading conditions considered here. This was consistent with the findings related to the sandwich panel response subjected to a single intense shock. Comparison of these results showed that optimized sandwich panels outperform solid plates under shock loading. An empirical method for prediction of the deflection and fracture of sandwich panels under two consecutive shocks – based on finding an effective peak over-pressure – was provided. Moreover, a limited number of simulations related to response and fracture of sandwich panels under multiple shocks with different material properties were performed to highlight the role of metal strength and ductility. In this set of simulations, square honeycomb sandwich panels made of four steels representing a relatively wide range of strength, strain hardening and ductility values were studied. For panels clamped at their edge, the observed failure mechanisms are core failure, top face failure and tearing at or close to the clamped edge. Failure diagrams for sandwich panels were constructed which reveal the fracture and failure mechanisms under various shock intensities for panels subjected to up to three consecutive shocks. The results complement previous studies on the behavior and fracture of these panels under high intensity dynamic loading and further highlights the potential of these panels for development of threat-resistant structural systems.     

夹层梁总体屈曲及皱曲的有限元计算

皱曲是夹层结构的一种短波屈曲模式,通常发生于夹心较厚或夹心刚度较低的情况。由于模型规模的限制,在常规有限元建模时通常将夹层板模拟为二维板单元,这种方法忽略了面板和夹心在厚度方向上的相互作用,无法计算出皱曲模式。针对上述问题,本文首先介绍了一个计算夹层结构总体屈曲和皱曲的统一理论,并将此理论的计算结果作为理论解。为了同时...     

碳纤维复合材料金字塔点阵结构制备工艺及力学性能研究

本文针对碳纤维复合材料点阵结构,从结构设计、制备工艺、平压性能、剪切性能等方面对其进行试验表征及理论模型研究.设计四种成型碳纤维复合材料金字塔点阵结构的思想,并采用一种新的制备工艺即预浸料二次成型工艺制备试样,试验结果表明,该工艺能最大程度发挥纤维增强潜力.通过实验揭示在平压载荷下杆件屈曲、杆件断裂、杆件分层脱胶失效机理,在剪切载荷下杆件屈曲、杆件分层、杆件脱胶失效机理,基于结构力学基础原理,建立相应理论模型,经过修正之后的理论模型均能较好预报典型载荷下力学性能.本文研究发现碳纤维复合材料金字塔点阵结构具有密度低、比强度大、比刚度高等优点,且芯子中具有大量空间,可以制备轻质多功能结构.     

金字塔栅格夹心夹层板动力响应分析

本文将金字塔形栅格夹心夹层板假设成均匀夹心夹层板,应用Reissner夹层板理论,对其自振频率以及在简谐荷载下的强迫振动进行了研究,并以简支板为例,得到其解析解,通过与有限元分析进行比较,两者结果吻合良好。并把金字塔形栅格夹层板与同质量实体板进行比较,得出金字塔形栅格夹层板具有更好动力性能。     

On the performance of truss panels with Kagomé cores

The performance characteristics of a truss core sandwich panel design based on the 3D Kagomé has been measured and compared with earlier simulations. Panels have been fabricated by investment casting and tested in compression, shear and bending. The isotropic nature of this core design has been confirmed. The superior performance relative to truss designs based on the tetrahedron has been demonstrated and attributed to the greater resistance to plastic buckling at the equivalent core density.