结构冲击畸变问题的直接相似方法研究

结构受冲击时由不同材料引起比例模型与全尺寸原型的畸变, 通常通过修正比例模型的速度或密度进行补偿. 然而传统的修正方法, 存在需预先测试结构响应、依赖特殊本构方程、不能反映动态过程的缺陷, 因而限制了相似理论在比例模型试验中的直接应用. 本文提出了一种不同材料畸变问题的直接相似方法. 它通过建立应变率区间上比例模型预测的流动屈服应力与原型流动屈服应力的最佳逼近关系, 直接获得了修正速度或修正密度的比例因子, 完成了比例模型与原型的动态相似关系. 基于Norton-Hoff, Cowper-Symonds, Johnson-Cook三种经典的本构模型, 研究了材料应变率敏感性特征参数、参考应变率、屈服应力、密度在动态相似关系中的作用. 并通过受质量冲击的折板结构算例, 验证了直接相似方法的有效性. 分析表明, 本文提出的直接相似方法不需要预先测试结构的响应, 不依赖特殊的本构方程、强调动态相似特性, 具有直接、高效、通用的特点. 此外, 动态相似关系的最佳逼近效果, 受材料应变率敏感性特征参数控制, 屈服应力、密度和参考应变率影响不大; 当比例模型应变率敏感性特征参数与原型相近, 可获得最佳逼近.      

结构冲击畸变问题的直接相似方法研究

结构受冲击时由不同材料引起比例模型与全尺寸原型的畸变,通常通过修正比例模型的速度或密度进行补偿.然而传统的修正方法,存在需预先测试结构响应、依赖特殊本构方程、不能反映动态过程的缺陷,因而限制了相似理论在比例模型试验中的直接应用.本文提出了一种不同材料畸变问题的直接相似方法.它通过建立应变率区间上比例模型预测的流动屈服应力与原型流动屈服应力的最佳逼近关系,直接获得了修正速度或修正密度的比例因子,完成了比例模型与原型的动态相似关系.基于Norton-Hoff, Cowper-Symonds, Johnson-Cook三种经典的本构模型,研究了材料应变率敏感性特征参数、参考应变率、屈服应力、密度在动态相似关系中的作用.并通过受质量冲击的折板结构算例,验证了直接相似方法的有效性.分析表明,本文提出的直接相似方法不需要预先测试结构的响应,不依赖特殊的本构方程、强调动态相似特性,具有直接、高效、通用的特点.此外,动态相似关系的最佳逼近效果,受材料应变率敏感性特征参数控制,屈服应力、密度和参考应变率影响不大;当比例模型应变率敏感性特征参数与原型相近,可获得最佳逼近.     

薄板在冲击载荷下线弹性理想塑性响应的相似性研究

对于比例模型和原型使用不同弹塑性材料的冲击相似性问题,由于弹性和塑性阶段材料特性的差别及其在不同变形阶段的弹性塑性共存现象,将导致原有的结构冲击相似性理论失效。基于薄板冲击问题的理论模型,采用方程分析方法重新推导了材料线弹性以及理想刚塑性共存时的冲击响应的相似律。提出了一种能够同时考虑弹性变形和塑性变形的结构缩放响应相似性分析的厚度补偿方法,并利用数值分析验证了提出方法的适用性。分析结果表明,使用厚度补偿方法得到的比例模型结构响应能够准确地预测原型结构的冲击响应。     

横向爆炸载荷下薄壁圆管的动态响应

采用实验研究、理论分析和有限元模拟相结合的方法，研究了横向爆炸载荷作用下薄壁圆管的动态响应。利用弹道冲击摆锤系统，对圆管在爆炸载荷下的动力响应进行了实验研究，分析了薄壁圆管的变形模式；基于地基梁模型，建立了横向爆炸载荷作用下圆管跨中挠度的理论模型，并进行了无量纲化；通过有限元模拟，分析了圆管的几何参数对其变形模式和跨中挠度的影响，并与理论结果进行了对比。研究结果表明:随着TNT药量增加圆管的变形区域和跨中挠度增大；圆管的长径比、厚度及爆炸载荷参数对圆管的变形模式有较大影响；理论预测、有限元模拟结果与实验结果吻合较好。     

轮胎破片冲击机身的非等比例相似模型研究

为降低机身结构抗冲击性能的实验成本,利用相似理论建立机身的非等比例缩放模型,开展模型实验是行之有效的方法。基于量纲分析的方法,建立Johnson-Cook线性应变率函数的修正关系;鉴于生产制造技术的限制,考虑扭曲厚度的非等比例机身模型对相似性行为的影响,采用指数函数法建立了非等比例模型的相似修正关系。通过对比实验中破片冲击过程的变形形态、靶板的应变时间历程曲线和最终变形轮廓,验证了数值模型的有效性。此外,分析了破片偏航姿态、机身材料、厚度和质量等因素对机身结构抗冲击性能的影响。结果表明:(1) 150 m/s的冲击速度下,破片冲击角度90o和着靶角度180o是最严苛的冲击条件。综合多种因素,分析认为3.5 mm厚的钛合金为机身结构的最佳选择,并以此作为全尺寸原型验证相似模型;另外,提出了一种可以快速获取缩比模型的设计方法。(2)应变率效应对轮胎破片冲击机身结构的影响并不显著,等比例缩放模型与原型结果吻合较好。(3)厚度扭曲的非等比例模型能够有效地预测原型结构的变形行为;虽然,在时间尺度上,模型与原型存在一定的偏差;但是,在空间尺度上,非等比例相似模型能够有效地修正扭曲厚度造成中心最大挠度的预测误差,修正后的最大误差不超过5.1%,这表明该方法能够有效地指导机身结构的相似模型设计。     

内压循环下薄壁圆筒的环向棘轮应变预测

对单轴和比例加载下的棘轮应变进行预测目前仍有较大困难。本文考虑将移动极限面加入材料双面本构模型中，对原提出的叠加型随动强化律进行了修正，可以对较多循环数的1Crl8Ni9Ti不锈钢薄壁圆管的环向棘轮应变做出预测。     

内爆炸载荷下泡沫铝夹芯圆管塑性动力响应及能量耗散机理

通过实验、理论和数值模拟研究泡沫铝夹芯空心圆管在内爆载荷作用下的动态变形模式及吸能机制.采用不同质量的球形乳化炸药进行爆炸试验.结构轴向变形分为3个区:大塑性变形区、绕塑性铰的刚性旋转区和无变形区.在考虑环向膜力和轴向弯矩的情况下,提出内爆作用下夹芯圆管动态响应的显式计算方法.通过建立基于三维Voronoi算法的泡沫芯有限元模型,探索结构能量耗散机制.通过实验观测到的泡沫铝夹芯空心圆管在内爆载荷作用下的变形机制,结合内外管的弯曲变形及芯层压缩,给出了结构在响应过程中能量吸收的理论解.以结构比吸能和外管中心挠度为控制参量求得夹芯圆管的最优解集.进一步研究炸药质量、内外管直径、壁厚及芯层轴向梯度排列方式对结构动态变形模式和吸能机制的影响.结果表明:内管壁厚对外管中心线的挠度影响较大,而芯层厚度和外管壁厚的影响较小;如果夹芯圆管的轴向梯度结构从管轴向对称面到两端边缘呈对称递减分布时,具有较好的抗爆性;数值计算和实验测试结果均与理论预测吻合.     

金属正交波纹夹芯结构的动态压缩响应

通过理论和数值方法，对冲击载荷下金属正交波纹夹芯结构的动态压缩响应进行了研究。考虑材料应变率影响，建立了金属正交波纹夹芯结构动态响应的理论模型，同时对它的动态压缩响应进行了有限元模拟。结果表明，考虑材料应变率影响的理论模型的预测结果与有限元模拟结果吻合较好。进一步对多层正交波纹夹芯结构的动态压缩响应进行了数值模拟，获得了不同速度冲击下的变形模式，分析了层数对其动态响应的影响。研究发现，通过增加层数能够有效地增强结构的缓冲吸能能力，但层数超过4层以后增强效果不明显。     

基于Cowper-Symonds方程的相似理论修正方法

针对应变率敏感材料冲击实验的指导需求,给出了一种传统相似理论的修正方法。该方法在已有的动态相似理论基础上,考虑了因实验时模型与全尺寸原型制造材料不同,而导致外载条件相似系数对应变率效应对结果造成的影响:通过引入Cowper-Symonds方程,重新推导了外载条件相似系数的计算公式,并对两种不同材料（是否应变率敏感）的缩放模型冲击实验结果进行讨论,表明该方法相较于传统理论能够准确给出外载条件相似系数、提高模型预测精度。     

远距离爆炸荷载作用下钢框架几何相似律研究

根据Π定理推导了远距离爆炸荷载作用下钢框架原型结构与缩比模型的几何相似律表达式。基于已有的钢框架子结构爆炸实验,采用AUTODYN建立了钢框架子结构数值模型,验证了流固耦合方法在结构爆炸响应分析中的可靠性。在此基础上,对比了流固耦合方法和解析爆炸边界方法在钢框架远距离爆炸数值模拟中的准确性和计算效率,结果表明,解析爆炸边界方法可以合理地模拟远距离爆炸荷载作用下钢框架的动态响应,且计算效率较高。最后,采用该方法分析了具有不同相似比的两层三跨钢框架结构在远距离爆炸荷载作用下的动态响应及毁伤效应,结果表明:该结构的动态响应和毁伤效应符合几何相似规律。     

High-Order Vibrations’ Dynamic Scaling Laws of Distorted Scaled Models of Thin-Walled Short Cylindrical Shells

In this study, we investigate the dynamic scaling laws of geometrically distorted models for predicting dynamic characteristics of thin-walled short cylindrical shells. Approximate and accurate analysis methods for obtaining the scaling laws are introduced. Two coefficient functions are established in deriving high-order scaling laws for a narrow range distorted model. Then a modified function is obtained by using numerical analysis, in order to modify the errors of wide range distorted models. The general form of the high-order scaling laws of thin-walled short cylindrical shells is also developed. To be practical, a process of detecting scaling laws by experimental operation is summarized, and the applicability of scaling laws is validated by using experimental data. Although there are some limitations in practice, the scaling laws of the thin-walled short cylindrical shell still have the ability to predict the prototype with good accuracy.     

冲击载荷作用下柱壳链中的弹性波传播简化模型及其解析解

柱壳链能引起波形的弥散,具备操控波形的潜力。建立了柱壳链结构的等效连续介质模型和细观有限元模型,研究了质量块冲击作用下柱壳链中的弹性应力波传播过程及其几何弥散特性。基于考虑横向惯性修正的Rayleigh-Love波动方程,建立了柱壳链在质量块冲击下的控制方程,采用Laplace变换及其逆变换获得了位移场、速度场和应变场的解析解,所得结果与细观有限元模拟结果较好吻合。结果表明,在冲击过程中应变和速度峰值均逐渐减小,应变峰值、振荡幅度和波形前沿宽度与泊松比和惯性半径相关,泊松比和惯性半径越大,应变峰值越小,应变分布振荡越剧烈,波形前沿宽度越宽。     

Thermomechanical vibration analysis of a functionally graded shell with flowing fluid

This paper reports the results of an investigation into the vibration of functionally graded cylindrical shells with flowing fluid, embedded in an elastic medium, under mechanical and thermal loads. By considering rotary inertia, the first-order shear deformation theory (FSDT) and the fluid velocity potential, the dynamic equation of functionally graded cylindrical shells with flowing fluid is derived. Here, heat conduction equation along the thickness of the shell is applied to determine the temperature distribution and material properties are assumed to be graded distribution along the thickness direction according to a power-law in terms of the volume fractions of the constituents. The equations of eigenvalue problem are obtained by using a modal expansion method. In numerical examples, effects of material composition, thermal loading, static axial loading, flow velocity, medium stiffness and shell geometry parameters on the free vibration characteristics are described. The new features in this paper are helpful for the application and the design of functionally graded cylindrical shells containing fluid flow.     

两参数轴向冲击载荷作用下圆柱壳弹塑性动力屈曲

研究圆柱壳在两参数轴向冲击载荷下的弹塑性动力屈曲问题，基本控制方程由弹塑性连续介质中关于加速度的最小原理获得，本构关系采用增量理论。研究表明：屈曲过程可划分为两相，两相之间由临界时间ｔ表征，并分别讨论了应力波对屈曲的影响，压缩波与弯曲波的相互作用及几何尺寸，材料参数，初始缺陷，载荷峰值及持续时间等诸多因素与动力屈曲的关系。     

On dynamic buckling phenomena in axially loaded elastic-plastic cylindrical shells

Some characteristic features of the dynamic inelastic buckling behaviour of cylindrical shells subjected to axial impact loads are discussed. It is shown that the material properties and their approximations in the plastic range influence the initial instability pattern and the final buckling shape of a shell having a given geometry. The phenomena of dynamic plastic buckling (when the entire length of a cylindrical shell wrinkles before the development of large radial displacements) and dynamic progressive buckling (when the folds in a cylindrical shell form sequentially) are analysed from the viewpoint of stress wave propagation resulting from an axial impact. It is shown that a high velocity impact causes an instantaneously applied load, with a maximum value at t=0 and whether or not this load causes an inelastic collapse depends on the magnitude of the initial kinetic energy.     

有限长圆柱壳受径向冲击的塑性动力屈曲分析

讨论两端固定的圆柱薄壳在均布外部冲击下的塑性动力屈曲。依据实验现象对位移场作出假设，用扰动法求得屈曲的扰动控制方程组，降阶后用标准的龙格库塔法进行数值求解。其中物理关系采用Ｌｅｖｙ－Ｍｉｓｅｓ流动理论，材料为刚线性强化模型。计算结果同Ｆｌｏｒｅｎｃｅ等的Ｂｅｓｓｅｌ函数解作了比较，对边界对屈曲的影响作了讨论。本文的结果对潜艇抗水下爆炸的研究有重要意义。     

Low-Dimensional Galerkin Models for Nonlinear Vibration and Instability Analysis of Cylindrical Shells

This paper discusses the derivation of discrete low-dimensional models for the non-linear vibration analysis of thin shells. In order to understand the peculiarities inherent to this class of structural problems, the non-linear vibrations and dynamic stability of a circular cylindrical shell subjected to dynamic axial loads are analyzed. This choice is based on the fact that cylindrical shells exhibit a highly non-linear behavior under both static and dynamic axial loads. Geometric non-linearities due to finite-amplitude shell motions are considered by using Donnell’s nonlinear shallow shell theory. A perturbation procedure, validated in previous studies, is used to derive a general expression for the non-linear vibration modes and the discretized equations of motion are obtained by the Galerkin method. The responses of several low-dimensional models are compared. These are used to study the influence of the modelling on the convergence of critical loads, bifurcation diagrams, attractors and large amplitude responses of the shell. It is shown that rather low-dimensional and properly selected models can describe with good accuracy the response of the shell up to very large vibration amplitudes.     

Dynamic limit analysis formulation for impact simulation of structural members

This paper introduces an extended concept of limit analysis to deal with the dynamic equilibrium condition considering the inertia and strain-rate effect for dynamic behavior of structures. The conventional limit analysis method has been applied to only static collapse analysis of structures without consideration of dynamic effects in the structural behavior. A dynamic formulation for the limit analysis has been derived for incremental analysis dealing with time integration, strain and stress evaluation, strain hardening, strain-rate hardening and thermal softening. The time dependent term in the governing equation is integrated with the WBZ-α method. The dynamic material behavior is described by the Johnson–Cook model in order to consider strain-rate hardening and thermal softening as well as strain hardening. Simulations have been carried out for impact analysis of a Taylor bar and an S-rail and their numerical results are compared with elasto-plastic explicit analysis results by LS-DYNA3D. Comparison demonstrates that the dynamic finite element limit analysis can predict the crashworthiness of structural members effectively with less effort and computing time than the commercial code compared. The crashworthiness of a structure with the rate-dependent constitutive model is also compared to that with the quasi-static constitutive relation in order to investigate the dynamic effect on deformation of structures.     

EXPERIMENTAL INVESTIGATION AND COMPUTER SIMULATION ON DYNAMIC BUCKLING BEHAVIOR OF LIQUID-FILLED CYLINDRICAL SHELLS UNDER AXIAL IMPACT

This article reports an experimental investigation on the axial impact buckling of thin metallic cylindrical shells fully filled with water. Low velocity impact tests are carried out by DHR-9401 drop hammer rig. The whole process of dynamic buckling is simulated using LS-DYNA computer code. The consistency between experimental observation and numerical simulation is quite satisfactory. The investigation indicates that quite high internal hydrodynamic pressure occurs inside the shell during the impact process. Under the combined action of the high internal pressure and axial compression plastic buckling occurs easily in the thin-walled shells and buckling modes take on regular and axisymmetric wrinkles. This project is supported by the National Natural Science Foundation of China(19672039) and the Shanxi Foundation for Returned Scholars from Abroad.     

纯弯曲下薄壁圆柱壳屈曲的非线性分析

为解决薄壁圆柱壳在纯弯曲下由于横截面的椭圆化而引起的屈曲几何非线性问题. 基本假设是改良的Brazier 简单理论,把圆柱壳的纯弯曲变形简化成一个两阶段的过程,分别求得纵向弯曲变形应变能和横截面变形应变能,然后利用最小势能原理求出作用力矩与杆端旋转角度的关系,最后分析可知:壳体长度参数越小,对应的圆柱壳壁越薄,非线性的影响越大;剪力大小参数越小,边界条件对椭圆化变形影响越小,非线性的影响越大.