夹具对复合材料加筋板剪切试验屈曲载荷的影响

复合材料加筋板在剪切载荷作用下的屈曲和后屈曲性能试验是难度较高的结构试验,载荷通常需要由设计合理的夹具传递到试件上,本文采用的是对拉式的剪切试验夹具.在试验中,由于引入的夹具是弹性体,与试件结合成一体,参与了屈曲过程,所以与理想的约束情况有差异.本文采用数值方法,模拟夹具对试验结果的影响,发现不同的夹持模型,对屈曲载荷...     

基于弧长法的加筋板后屈曲特性分析及试验

作为飞机上重要的承载部件,加筋壁板在发生初始屈曲后仍具有较强的后屈曲承载能力,因此研究其后屈曲特性对于确定破坏载荷具有重要意义。传统的特征值屈曲分析是以小位移小应变的线弹性理论为基础的,且不考虑结构在受载过程中结构构形的变化,因此误差较大。本文采用Riks弧长法,结合材料弹塑性理论对铝合金整体加筋壁板轴压加载后的屈曲破坏过程、传载机制、极限载荷进行了研究,并进行了轴压加载的试验验证,得到了加载过程中的应力、应变曲线以及极限载荷,还对后屈曲破坏形式进行了分析。数值模拟结果表明:本文研究的整体加筋板初始屈曲发生在蒙皮,后屈曲过程筋条是主要的承载部位,与试验中观察到的现象一致;试验中加筋板最终破坏部位发生在筋与蒙皮连接处,有限元模拟结果与试验中加筋板的最终破坏部位一致;数值模拟得到的极限载荷与试验的相对误差在5%以内。这表明基于弧长法的后屈曲计算能够准确跟踪整体加筋板的后屈曲平衡路径和预测极限载荷。     

含预置损伤复合材料加筋板的单轴压缩屈曲分析

通过试验和有限元方法分析了单轴压缩下加筋板的失效模式.研究了三种预置损伤位置及四种损伤尺寸的复合材料T型加筋板的线性及非线性屈曲行为,比较了损伤对临界屈曲载荷和最大失效载荷的影响.研究结果表明:损伤位置在桁条间蒙皮时,损伤的尺寸对其临界屈曲载荷和最大失效载荷影响较小;损伤位置在桁条区蒙皮时,加筋板的临界屈曲载荷随损伤尺寸的增加而明显降低,最大降低50%;损伤位置在桁条边凸缘处蒙皮时,加筋板最大失效载荷所受影响随损伤尺寸的增加而明显降低,最大降低25%.从而得到了复合材料加筋板临界屈曲载荷比和最大失效载荷比与损伤位置及尺寸的关系图.     

加筋壁板轴压载荷下后屈曲稳定性试验研究

对11种构型的民用飞机机身加筋曲板在轴压载荷下后屈曲承载能力进行了试验和工程算法研究,深入探索了机身壁板的各种破坏模式,对极限法、Johnson）物线法与欧拉法三种工程算法比较,并且把试验结果与计算结果进行了对比。研究结果表明：壁板后屈曲轴压许用值与桁条剖面积和蒙皮厚度成线形关系,主要取决于桁条剖面积;蒙皮的局部屈曲应力对初始缺陷敏感,但局部屈曲应力的偏差对壁板的轴压破坏载荷影响不明显;与工程计算结果对比发现Johnson抛物线法计算的破坏轴压与试验结果吻合较好。     

具有分层损伤的不同加筋形式复合材料层合板的后屈曲性态研究

基于板的一阶剪切理论和V on-K arm an大挠度理论,分别推导了复合材料层合板和层合梁的几何非线性有限元列式,提出了含嵌入分层的复合材料加筋层合板在受压缩载荷作用下的后屈曲有限元分析方法,对在板厚方向具有不同分层位置的加筋板结构进行了有限元数值分析,研究了不同的加筋方式及筋的分布对具有分层损伤的复合材料加筋层合板的后屈曲性态的影响,所得结果对确定在压缩载荷作用下含损伤复合材料加筋层合板的剩余承载能力具有参考价值。     

短柱型复合材料加筋壁板轴向压缩破坏分析方法研究

复合材料加筋结构可作为航空结构中的承力部件,其损伤与破坏对航空器的结构安全和服役性能至关重要．本文通过试验和数值仿真手段研究了短柱型复合材料结构压缩失效机理和极限承载力．通过短柱型单加筋板的轴向压缩破坏试验,分析梳理出界面脱粘和材料压溃两种典型失效形式;分别建立加筋板壳单元模型和实体单元模型,引入内聚力模型和Hashin 准则描述界面脱粘效应与材料破坏,结果表明壳单元模型配合内聚力模型和Hashin 准则可以有效地预测加筋板的极限承载力．分别讨论了加筋板长度、筋条高度、筋条/蒙皮刚度比等参数对加筋板的屈曲承载力的影响,为短柱型复合材料加筋壁板压缩损伤与破坏预测分析提供有益的参考．     

新的复合材料格栅加筋板的平铺等效刚度法

针对薄壁复合材料格栅加筋结构的受力特点,在改进原有力学假设的基础之上,推导了一种新的平铺等效刚度计算方法,它充分考虑了筋条和面板之间的相互作用.通过格栅单元结构布局形式的参数化表示,建立了通用的力学分析模型;该模型可用于分析各种结构布局形式和面板铺层方式下的结构总体屈曲问题,故对于航空航天结构设计非常有用.结合Rayleigh-Ritz方法,推导出了求解格栅加筋板屈曲载荷的通用线性特征方程;最后,分析了多种类型格栅结构的算例,并与现有的各种方法进行了比较,结果更为精确,因而对格栅加筋结构的优化设计具有很好的应用价值.     

水下爆炸载荷作用下环肋加筋圆柱壳结构的弹塑性动力屈曲

为研究水下爆炸载荷作用下潜艇结构的动力屈曲现象,以潜艇耐压结构的简化模型环肋加筋圆 柱壳结构为研究对象,建立流固耦合有限元分析模型,应用瞬态有限元分析程序MSC.Dytran对该结构在水 下爆炸冲击载荷作用下的弹塑性动力屈曲行为进行研究,基于Budiansky-Roth准则和Southwell方法确定环 肋加筋圆柱壳结构的临界屈曲载荷,讨论结构动力屈曲的影响因素如载荷强度、网格密度、径厚比、长径比、加 筋截面间距、加筋尺寸等对环肋加筋圆柱壳结构动屈曲模态和临界屈曲载荷的影响。结果表明:采用建立的 流固耦合有限元分析模型,应用动力瞬态有限元软件MSC.Dytran可以对加筋圆柱壳结构的动力屈曲行为进 行模拟,模型网格尺寸大小、结构几何参数对结构的动力屈曲临界载荷都有一定的影响,其中加筋圆柱壳结构 的径厚比对结构的动力屈曲临界载荷影响最为显著。     

基于代理模型和等效刚度模型的加筋柱壳混合优化设计

针对轴压作用下的加筋柱壳后屈曲性能优化计算较大的问题,本文提出了一种基于代理模型和等效刚度模型的混合优化策略,即运用基于等效刚度的平铺模型进行有限元后屈曲分析以代替试验设计中大量的精细加筋模型分析,并通过控制等效模型的单元尺寸来调整其分析精度,而等效刚度模型计算时长仅约为精细加筋模型的1/3。对构建的代理模型采用多岛遗传算法进行极限承载力等约束下的轻量化设计,调用精细模型有限元后屈曲分析对代理模型进行更新,从而保证代理模型的拟合精度并得到优化解。工程算例结果表明,本文提出的混合优化方法,使加筋柱壳结构在满足承载力情况下减重效果明显。     

工字型加筋复合材料壁板的压缩屈曲行为实验研究

在复合材料结构整个屈曲承载过程中,从微观开始发生局部的纤维断裂、基体微裂纹等损伤,并随着屈曲程度的增加和屈曲模式的转化逐渐发生分层扩展。采用实验与数值计算相结合的方法,本文研究了工字型加筋壁板复合材料结构在压缩载荷作用下的屈曲行为。采用无损光学手段来非接触检测壁板表面的全场屈曲挠度,捕捉屈曲模态演化过程。基于有限元的数值模拟,预测了工字型加筋壁板复合材料结构的屈曲与后屈曲行为,用定量的实验数据来对比数值预测的壁板屈曲形态,表明实验和数值结果的离面挠度分布具有一致性。     

开孔平板的剪切稳定性实验

对四边简支和四周边受均匀剪切力的矩形薄平板的屈曲失稳,作了实验分析及数值计算.用作者所设计的剪切试验装置,对一组开孔及开孔后加强的薄平板进行了剪切稳定性试验,求得薄平板失稳时的载荷——挠度曲线及失稳波形,由曲线上拐点来确定平板失稳临界载荷,并将实验结果与有限元数值计算结果作了比较.     

Edge-compression fixture for buckling studies of corrugated board panels

A test fixture, developed for evaluating the preand postbuckling response of simply supported, nearly flat, rectangular corrugated board panels subjected to edge compression is evaluated. The test fixture enables loading of panels into the postbuckling regime until collapse. The shadowmoiré method verified that buckling in the first mode occurred, and that there was symmetry of the adge-boundary conditions. Through an iterative regression model, experimental curves of load versus out-of-plane displacement for isotropic panels were fitted to an equation governing the nonlinear postbuckling response. This method provides the critical buckling load, a postbuckling parameter and the amplitude of initial imperfection of the panel. Comparison with analytical results revealed that simply supported boundary conditions were closely achieved. Examination of compressively loaded corrugated board panels showed that collapse occurred due to compressive failures of the facings in the highly stressed edge regions without severe influence from stress concentrations at load introduction and edge supports.     

Buckling analysis of functionally graded material (FGM) sandwich truncated conical shells reinforced by FGM stiffeners filled inside by elastic foundations

An analytical solution for buckling of an eccentrically stiffened sandwich truncated conical shell is investigated. The shell consists of two functionally graded material (FGM) coating layers and a core layer which are metal or ceramic subjected to an axial compressive load and an external uniform pressure. Shells are reinforced by stringers and rings, in which the material properties of shells and stiffeners are graded in the thickness direction following a general sigmoid law distribution. Two models of coated shell-stiffener arrangements are investigated. The change of the spacing between stringers in the meridional direction is taken into account. A couple set of three-variable-coefficient partial differential equations in terms of displacement components are solved by the Galerkin method. A closed-form expression for determining the buckling load is obtained. The numerical examples are presented and compared with previous works.     

薄壁加筋肋圆柱壳稳定性分析的参数化研究

针对在轴向载荷作用下的正置、正交网格形式的薄壁加筋肋圆柱壳结构，利用有限元程序，对薄壁加筋肋圆柱壳稳定性分析进行了参数化研究，得到了进行结构优化设计的准则，对于给定的设计载荷，当结构参数位于某一个局部失稳与整体失稳的临界区域时，结构的重量最轻。提出了基于有限元分析进行结构优化设计的策略，利用优化策略，获得了一薄壁加筋肋圆柱壳结构的优化设计结果，同时给出了粘合刚度简化模型与有限元计算结果的比较。     

正交各向异性加筋板屈曲分析方法研究

为简化正交各向异性加筋板屈曲分析,本文将筋条位移场用其所在位置的板的位移表达,建立加筋板总势能,通过离散位移场,利用最小势能原理,推导出基于里兹法的正交各向异性加筋板屈曲分析控制方程,采用Matlab进行求解.基于本文推导的方程对单筋和三筋加筋板在不同压剪比下的屈曲荷载和模态进行分析,得到与Abaqus基本一致的结果.加筋板的屈曲荷载随着筋条数增加明显增大;压剪比为1∶1时,各阶屈曲荷载均最小;随着位移函数阶数提高,本文算法计算精度提高,但相应的计算量也显著增大.     

Snap-through buckling of eccentrically stiffened shallow spherical caps

The problem of snap-through buckling of a clamped, eccentrically stiffened shallow spherical cap is considered under quasi-statically applied uniform pressure and a special case of dynamically applied uniform pressure. This dynamic case is the constant load infinite duration case (step time-function) and it represents an extreme case of blast loading-large decay time, small decay rate.The analysis is based on the nonlinear shallow shell equations under the assumption of axisymmetric deformations and linear stress-strain laws. The eccentric stiff eners are disposed orthogonally along directions of principal curvature in such a way that the smeared mass, and extensional and flexural stiffnesses are constant. The stiffeners are also taken to be one-sided with constant eccentricity, and the stiffener-shell connection is assumed to be monolithic.The method developed in an earlier paper is employed. In this method, critical pressures are associated with characteristics of the total potential surface in the configuration space of the generalized coordinates.In addition, buckling of the complete thin eccentrically stiffened spherical shell under uniform quasi-statically applied pressure is considered, and these results are used to check the numerical answers. The complete spherical shell is stiffened in the same manner as the shallow cap.The results are presented in graphical form as load parameter vs initial rise parameter. Geometric configurations corresponding to isotropic, lightly stiffened, moderately stiffened and heavily stiffened geometries are considered. By lightly stiffened geometry one means that most of the extensional stiffness is provided by the thin shell. A computer program was written to solve for critical pressures. The Georgia Tech Univac 1108 high speed digital computer was used for this purpose.     

静力预加载环向加筋圆柱壳的轴向流-固冲击屈曲

将初缺陷放大准则应用于静力预加载环向加筋圆柱壳结构受轴向流-固冲击加载作用时的几何非线性动力屈曲研究中。运用Galerkin方法推导出壳体-肋骨系统的动力屈曲控制方程,并且采用Runge-Kutta法进行数值求解。着重分析了静力预加载荷对结构屈曲性态及抗轴向冲击能力的影响。     

Repeated buckling and its influence on the geometrical imperfections of stiffened cylindrical shells under combined loading

The present experimental study aims at providing better inputs for improvement of the buckling load predictions of stiffened cylindrical shells subjected to combined loading. The work focuses on two main factors which considerably affect the combined buckling load of stiffened shells, namely geometric imperfections and boundary conditions. Six shells with nominal simple supports were tested under various combinations of axial compression and external pressure. The vibration correlation technique is employed to define the real boundary conditions. The geometric imperfections of the integrally stiffened shells are measured in the present experiments in situ and are used as inputs to a multimode analysis which yields the corresponding “knockdown” factor for various combinations of loading. Thus, when employing the repeated buckling procedure for obtaining interaction curves, each point on the curve is adjusted (using the multimode analysis) for the measured “new” surface of the shell and this results in more realistic interaction curves. The geometrical imperfections of the preloaded shells can also serve as an input to the International Imperfection Data Bank for future studies on the correlation between the manufacturing method of the shell and their geometric imperfections.