含不同形状分层缺陷蜂窝夹层板的压缩性能

对含面板/夹芯界面中央分层缺陷复合材料蜂窝夹层板的压缩性能进行了试验研究和理论分析,考察了一种圆形分层和2种矩形分层缺陷对其压缩强度的影响,并采用子层局部屈曲模型对压缩强度进行了计算。结果表明：无缺陷夹层板表现为总体失稳破坏,而对于含分层缺陷的夹层板,则视分层形状及其大小的不同而表现出不同的破坏机制。对于矩形缺陷的长边与载荷方向垂直的夹层板,一般情况下面板子层局部屈曲对夹层板的最终破坏不起控制作用;对于矩形缺陷的长边与载荷方向平行的夹层板,表现为总体失稳破坏。压缩破坏过程中,面板子层屈曲起控制作用的夹层板,子层局部屈曲模型能够比较精确地预测其压缩强度。     

基于多尺度方法的蜂窝夹层复合材料结构轴向压缩稳定性

为有效预测蜂窝夹层复合材料结构压缩失稳载荷和破坏模式,本文基于层压板宏细观多尺度数值分析模型,研究蜂窝夹层复合材料结构在轴向压缩载荷下的屈曲稳定性。基于改进的通用单胞理论模型,并结合ABAQUS用户自定义子程序接口,建立蜂窝夹层复合材料结构宏细观数值模型,预报蜂窝夹层复合材料结构失效载荷和破坏模式,并与试验结果对照,验证了模型的有效性。结果表明:通过本文建立的数值模型可以有效预测蜂窝夹层复合材料结构在压缩载荷下的失稳载荷和破坏模式,其一阶失稳载荷为128.12 kN,与试验结果误差为4.58%,蜂窝夹层复合材料结构破坏模式为先发生屈曲失稳,然后迅速破坏。      

等腰梯形蜂窝芯玻璃钢夹芯板的面内压缩性能

为研究等腰梯形蜂窝芯玻璃钢夹芯板面内压缩破坏机制, 利用材料试验机对夹芯板面内压缩性能进行了试验测试, 并开展了模拟研究。结果表明: 夹芯板的面内压缩破坏方式主要有面板折断、夹芯板屈曲失稳和夹芯板中面板与蜂窝芯脱粘3种类型。面板为夹芯板面内压缩的主要承载构件, 蜂窝芯对面板起到固支作用。面板结构参数与材料参数为影响夹芯板面内压缩抗压强度与抗压刚度主要因素, 多数蜂窝芯的结构参数与材料参数对夹芯板面内压缩抗压强度的影响微弱, 而个别蜂窝芯的结构参数对夹芯板面内压缩抗压刚度的影响比较显著。夹芯板体积一定时, 随着蜂窝芯胞体单元数量的增加, 夹芯板面内压缩的抗压强度与抗压刚度逐渐增大。      

等腰梯形蜂窝玻璃钢夹芯板的侧压性能

使用材料试验机对等腰梯形蜂窝芯玻璃钢夹芯板面的内压缩性能进行了实验测试与模拟研究。结果表明,夹芯板面内压缩的破坏方式主要有面板折断、夹芯板屈曲失稳及面板和蜂窝脱粘。面板是夹芯板面内压缩的主要承载构件,蜂窝芯对面板起固支作用。面板的结构参数和材料参数是影响夹芯板面内压缩抗压强度与承载应力的主要因素,蜂窝芯的结构参数和材料参数对夹芯板面内压缩抗压强度的影响较小,而蜂窝芯的高度对夹芯板面内压缩承载应力有显著的影响。     

金属蜂窝夹芯板疲劳行为的试验研究

金属蜂窝夹芯板结构在航空、航天领域中已得到了广泛的应用.本文首先简单介绍了金属蜂窝夹芯板的结构及特点,然后针对两个不同方向的金属蜂窝夹芯板进行了三点弯曲疲劳试验,测试了在不同应力水平下夹芯板的疲劳寿命,得到了该夹芯板的三点弯曲疲劳极限.试验结果表明,在W方向,夹芯板的主要疲劳破坏模式为蜂窝芯子之间的脱粘断裂,在L方向,夹芯板的主要疲劳破坏模式为蜂窝芯子和盖板之间焊点的开裂.     

浮冰碰撞下蜂窝金属夹芯板动态响应研究EI北大核心CSCD

采用非线性有限元软件ANSYS/LS-DYNA,结合混凝土冰材料数值模型,建立了楔形冰碰撞下蜂窝金属夹芯板动态响应数值仿真模型,得到了碰撞过程的冲击力时间曲线和冲击力位移曲线、蜂窝金属夹芯板的变形以及冲击能量分配情况,并开展了楔形冰-蜂窝金属夹芯板碰撞冲击试验验证。研究结果表明,楔形冰碰撞下蜂窝金属夹芯板上面板表现为局部凹陷与整体弯曲的耦合变形模式,下面板表现为整体弯曲变形模式,冲击能量转化为蜂窝金属夹芯板的变形能和楔形冰的回弹动能以及冰体破碎耗散能量,数值仿真与试验结果吻合较好,验证了数值计算模型的准确性。在此基础上,研究了浮冰碰撞冲击位置以及蜂窝芯层厚度对其动态响应及能量分配的影响规律。     

蜂窝金属夹芯板重复冲击动态响应研究

蜂窝金属及其夹芯结构是一种物理功能与结构一体化的新型轻质高强结构,广泛应用于结构轻量化与碰撞冲击防护领域。采用ABAQUS非线性有限元软件建立了蜂窝金属夹芯板(honeycomb sandwich panel,HSP)结构动态冲击数值仿真模型,数值仿真计算结果与文献实验结果吻合较好,验证了数值仿真模型的正确性。在此基础上,开展了重复冲击载荷作用下蜂窝金属夹芯板结构动态响应研究,得到了重复冲击力时程曲线、动态变形时程曲线、冲击力位移曲线以及最终挠度,分析了冲击能量、蜂窝壁厚以及上、下面板厚度分配对蜂窝金属夹芯板结构重复冲击动态响应的影响规律。研究结果表明,重复冲击载荷作用下蜂窝金属夹芯板结构上、下面板弯曲变形以及蜂窝芯层压缩变形逐渐积累,蜂窝芯层薄壁结构逐渐达到密实化,结构抗弯刚度逐渐上升,变形增量逐渐减小,结构整体能量吸收率下降。通过调节蜂窝壁厚和上、下面板厚度分配可以显著调节蜂窝金属夹芯板结构重复冲击动态响应与能量吸收性能。     

钎焊蜂窝铝板侧压变形模式分析研究

研究了钎焊蜂窝铝板侧压试验以及侧压变形模式,结果表明,钎焊蜂窝铝板的纵向侧压强度高于横向侧压强度;钎焊铝蜂窝板纵向和横向侧压变形均经历弹性变形、塑性变形和整体失稳3个阶段;在塑性变形阶段,纵向侧压时与双层壁板相焊合的面板区域轴向内凹,发生蜂格内酒窝型屈曲,横向侧压时与单层壁板相焊合的面板区域轴向外凸,发生蜂窝芯子剪切皱折失稳,纵、横向变形模式与内部蜂窝芯排列方式相关.     

复合材料工型梁压缩失效模式试验与仿真分析研究

复合材料工型梁是飞机舱门结构中的重要承力部件,其在压缩载荷下的失稳行为和损伤特性是工程设计中关注的要点。为了研究复合材料工型梁的压缩性能和失效模式,开展了轴向压缩试验和数值仿真计算。选取改进的Hashin准则判定层内损伤,引入内聚力胶层单元模拟层间损伤,并采用一种新的基于复合材料破坏现象的刚度退化模型对材料的性能进行折减。在模型中综合考虑了纤维扭折和翼缘侧向支撑作用对材料性能压缩失效的影响。计算得到的载荷-位移曲线、载荷-应变曲线、破坏模式以及破坏载荷均与试验结果符合较好,验证了模型的准确性。基于经试验验证后的模型,对工型梁截面进行了参数化分析,研究了长宽比、翼缘宽厚比对复合材料工型梁屈曲性能和承载能力的影响规律,为实际工程结构优化及选型提供了参考。     

GLARE层板挤压渐进损伤分析

对GLARE36/5层板进行挤压性能试验研究,采用超声C扫描、断口微距拍摄和扫描电子显微镜等方法观测GLARE层板挤压渐进损伤过程和最终破坏模式。结果表明:GLARE层板挤压起始损伤为铝合金塑性变形;损伤扩展阶段,0°纤维主要承受挤压正应力,铝合金塑性变形增大,铺层间分层起始并扩展;0°纤维屈曲折断后层内纤维基体损伤和分层损伤急剧扩展,层板最终发生挤压破坏。将GLARE层板挤压失效分为层内失效和层间失效,采用应变描述的Hashin准则和界面单元方法并引入金属塑性建立GLARE层板挤压渐进损伤数值模型,数值模型对层板损伤起始位置、分层产生位置、损伤演化过程、最终破坏模式及破坏载荷进行了预测,计算结果与试验结果吻合较好,说明该计算方法能够有效模拟GLARE层板挤压渐进损伤性能。      

Investigation on the square cell honeycomb structures under axial loading

To investigate into the collapse of a sandwich panel or beam with a square cell honeycomb, the novel plate model and beam model are developed according to the cross-sectional symmetry of the cell. The treble series solution of buckling mode is presented, and the formulas of critical compressive stress on skins are derived. The honeycomb sandwich panels are classified as thin, medium and thick plates based on their failure forms. It is found that the different kinds of cells have different buckling modes and different parameter governing equations. A new iterative optimization design method for a square honeycomb sandwich panel is developed and the curves of critical compressive stresses with geometrical parameters are provided in details. Finally, the 3D finite element numeric simulations have validated the formulas presented by this paper. Our study reveals some mechanical characteristics of the square honeycomb sandwich structures.     

Fracture test for double cantilever beam of honeycomb sandwich panels

A modified double cantilever beam (DCB) test geometry is designed to investigate the fracture behavior of honeycomb sandwich panels containing embedded artificial pre-crack, and measure the strain energy release rate of the laminate facesheet/honeycomb cores interface. However, in terms of our DCB fracture test, owing to that the pre-crack does not propagate expectedly along the interface of facesheet/honeycomb core, a new fracture mode, namely IKP (initiation of interlaminar delamination, kinking into facesheet and propagation of interlaminar delamination), has been found.     

Damage Modeling of Notched Graphite/Epoxy Sandwich Panels in Compression

Open-hole honeycomb sandwich panels with woven graphite/epoxy facesheets and Nomex cores were tested uniaxially in compression to characterize their damage tolerance. A plain weave T-300 graphite fiber fabric was used for the facesheets in two stacking sequences: [45/0₂] and [0₃]. Observations of macroscopic sub-critical damage behavior were different in the two material systems. Linear damage zones (LDZ), consisting of fiber micro-buckles and extensive delamination, were typically observed in the [0₃] material. The [45/0₂] material exhibited a delamination/bulge zone (DBZ), which consisted of an out-of-plane curved deformation of the outer 45° ply accompanied by a delamination from the interior 0° plies. Modeling of these apparently distinct failure modes, and comparison to experimental data, revealed that the only mode representative of damage tolerant behavior is linear damage zone formation and propagation for both material systems, and that the delamination/bulge behavior is a secondary phenomenon.     

Compression and bending performances of carbon fiber reinforced lattice-core sandwich composites

To restrict debonding, carbon fiber reinforced lattice-core sandwich composites with compliant skins were designed and manufactured. Compression behaviors of the lattice composites and sandwich columns with different skin thicknesses were tested. Bending performances of the sandwich panels were explored by three-point bending experiments. Two typical failure mechanisms of the lattice-core sandwich structures, delaminating and local buckling were revealed by the experiments. Failure criteria were suggested and gave consistent analytical predictions. For panels with stiff skins, delamination is the dominant failure style. Cell dimensions, fracture toughness of the adhesives and the strength of the sandwich skin decide the critical load capacity of the lattice-core sandwich structure. The mono-cell buckling and the succeeding local buckling are dominant for the sandwich structures with more compliant skin sheets. Debonding is restricted within one cell in bending and two cells in compression for lattice-core sandwich panels with compliant face sheets and softer lattice cores.     

明胶鸟弹撞击复合材料蜂窝夹芯板试验

开展明胶鸟弹撞击复合材料蜂窝夹芯板试验,研究夹芯结构在软体高速冲击下的损伤形式,分析相关因素对结构动态响应结果的影响。通过CT扫描对复合材料蜂窝夹芯板内部进行检测可知,面板出现分层、基体开裂、纤维断裂、凹陷、向胞内屈曲等损伤形式,蜂窝芯出现芯材压溃、与面板脱粘的损伤形式;分析复合材料蜂窝夹芯板后面板的动态变形过程及撞击中心处位移-时间数据可知,复合材料蜂窝夹芯板在撞击过程中出现由全局弯曲变形主导和局部变形主导的两种变形模式;通过对比不同工况下的复合材料蜂窝夹芯板损伤程度可知,复合材料蜂窝夹芯板损伤程度随鸟弹撞击速度的增加而增大;蜂窝芯高度为10 mm的复合材料蜂窝夹芯板较蜂窝芯高度为5 mm的复合材料蜂窝夹芯板的损伤程度大;初始动能较大的球形鸟弹较圆柱形鸟弹对复合材料蜂窝夹芯板造成的冲击损伤程度更大。      

Local buckling of stitched composite laminate

Due to relatively low interlaminar strength, delamination is a common failure mode of composite laminates. Through-thickness stitching is shown to improve the delamination resistance of laminated composites. Under in-plane compressive loading, significant strength reduction occurs due to coupling between delamination and delamination buckling. In this paper, an energy-based model was developed to predict the effect of critical stitching parameters on the delamination buckling strength of stitched laminates. Excellent agreement was found between the model results and a corresponding finite element analysis.