粘塑性薄壁管中复合应力波的传播特性研究

以本构关系一般理论为基础,导出了计及材料功硬化效应和应变率硬化效应的粘塑性薄壁管的本构关系及管中复合应力波的控制方程,应用有限差分方法研究了在压扭复合冲击载荷作用下粘塑性薄壁管中复合应力波的传播特性与演化规律,分析了复合应力波的耦合效应以及薄壁管中粘塑性参数和功硬化效应对复合应力波传播与演化规律的影响,并对有关现象进行了分析和解释。     

相变复合波在伪弹性TiNi合金薄壁管中的传播

相变可以改变材料的性质,从而严重影响波在介质中传播的结构。采用考虑静水压力和偏应力联合作用的增量型相变本构模型,研究了在拉(压)-扭联合作用下半无限长TiNi合金薄壁管内相变复合波的传播规律。基于广义特征理论分析了相变复合波的特征波速及简单波解的基本性质。利用数值方法研究了两种典型情况下管内相变耦合波传播的规律,管内传播的应力路径和波的结构与初始状态及加载幅值有关,展现出和普通弹塑性材料截然不同的性质。     

单轴循环载荷下镁合金宏观塑性本构关系研究

基于微观织构演化,本文对镁合金的宏观塑性本构模型进行了改进,得到了室温下镁合金AZ31B和AZ61A单轴循环拉压载荷作用下的应力应变曲线。模型中区分了滑移、孪晶与去孪三种不同微观塑性变形机制,并且研究了它们对材料宏观循环塑性行为的影响。通过引入初始非零背应力来模拟循环应力应变曲线中拉压不对称性,给出了材料在单轴循环拉压载荷下背应力及屈服面的演化规律,并运用线性预测塑性回拉技术与隐式积分法求解相应的非线性方程组,编写了与.ABAQUS接口的UMAT用户子程序。预测与实验结果的比较显示该模型能较好地模拟镁合金材料在单轴循环拉压载荷作用下的力学行为,具有较高的准确性与良好的实用性。     

金属拉扭强度关于材料声速及加载速率最小二乘法的回归模型

为了研究不同加载速率下金属的拉扭强度及其预测方法,利用声发射检测仪及电子拉扭试验机分别对铸铁和中碳钢标准试件进行了声速测定及不同加载速率、加载路径下的拉伸-扭转组合变形试验,得到了各试件材料的声速值及相应加载方案下的载荷-变形曲线;根据平面应力状态及强度理论,推导出了材料拉扭破坏的最大正应力、最大剪应力;利用试验中采集的最大轴力、最大扭矩计算得到了材料的拉扭破坏应力、破坏面方向;基于最小二乘法拟合得到了材料拉扭强度关于材料声速值、拉伸与扭转加载速率的多元回归模型。研究表明:随着拉伸与扭转加载速率的增加,铸铁、碳钢的破坏应力分别呈现总体上升、总体下降的趋势;相同加载速率、不同加载路径下材料的破坏强度各不相同;建立的回归模型能较好地预测给定材料在不同加载速率下的破坏应力,并以此建立塑性及脆性材料的拉扭强度条件。     

温度对高应变率扭-拉复合加载下形状记忆合金本构关系影响的研究

利用分离式扭-拉复合加载Hopkinson杆装置,在20℃和500℃下研究了温度对高应变率扭-拉复合加载下铁基形状记忆合金本构的影响,试验结果表明：该材料在高应变率扭-拉复合加载下的名义剪切屈服强度、剪切强度极限和名义拉伸屈服极限、拉伸强度极限均随温度的升高而降低,拉伸和扭转之间具有相互藕合作用。     

304不锈钢室温单轴循环棘轮行为的粘塑性本构描述

在统一粘塑性循环本构模型的框架下对循环硬化的304不锈钢的单轴棘轮行为进行了本构描述。模型中通过随动硬化背应力演化和各向同性变形阻力演化对304不锈钢在非对称应力循环下的循环附加硬化和循环流动特性进行了分析，同时考虑了加载历史对循环棘轮行为的影响。将模型应用于304不锈钢室温单轴循环棘轮行为及其对加载历史依赖性的描述中，预言结果与实验结果吻合较好。     

多功能SHPB装置及水泥石材料的动态性能研究

为了研究在一定温度和压力下的水泥石的动态力学性能，研制了多功能ＳＨＰＢ材料动态性能测试装置，该装置可分别进行材料的拉伸，压缩，扭转性能测试，拉，压试验可以在带围压和温度的三向应力状态下进行，文中还对水泥石改性材料的动态力学性能进行了实验研究。     

径向惯性对薄壁圆管中弹塑性复合应力波传播的影响

弹塑性压扭复合应力波在薄壁管中的传播特性,已得到较为深入的研究,但为得到简单波解,大部分研究忽略了薄壁圆管中与径向惯性有关的周向应力σθ的影响。该文采用便于动态数值方法应用的增量型弹塑性本构关系,应用有限差分数值方法,计算了考虑径向惯性效应的弹塑性薄壁管中复合应力波的演化规律和传播特性,并与无径向惯性效应的计算结果作了对比,结果表明薄壁管中的径向惯性效应对弹塑性复合应力的传播有较大的影响。     

扭转预应变对35CrMo钢低周疲劳性能的影响

自行设计了疲劳和扭转两用的试样,通过对试件预扭转不同的角度,系统研究35CrMo钢在不同扭转预应变下的低周疲劳性能,分析了扭转预应变后35CrMo钢的循环硬化软化特性、滞后回线、塑性应变能及循环弹性模量的变化规律,并对疲劳断口进行扫描电镜分析。结果表明:4种预扭转处理过的试件均表现出明显的循环软化行为,且循环软化规律及衰减的程度基本相同;循环应力范围及疲劳寿命随着预扭转角的增大而降低;应力应变滞后回线中加卸载曲线间的宽度随着预扭转角的增大而减小;塑性应变能都随着循环次数的增大而增加,且随着预扭转角的增大其增大速率下降;循环弹性模量都随着循环次数的增加而逐渐降低,且随着预扭转角的增大其衰减趋势减缓。     

需要考虑材料泊松比的某些塑性力学问题

本文例举了用测应变值确定受拉扭的薄壁管外载,受内压的封闭薄壁圆管在比例加载下的应变分量比值,以及平面应变条件下的三种初始屈服准则,说明对于这些塑性力学问题考虑材料真实泊松比 v 的必要性.     

Effect of creep prestrain on subsequent plastic deformation

The effect of creep prestrain on subsequent plastic deformation is experimentally investigated. The experiments are performed by subjecting thin-walled tubular specimens of stainless steel SUS 304 after creep prestraining to combined axial load and torsion at room temperature to 600°C. The stress-strain relations subsequent to creep prestrain are determined under combined stress state with and without temperature changes in prestraining and subsequent plastic straining. On the experimental results, the plastic hardening effects by creep prestrain are discussed under various temperature conditions. The subsequent stress-strain relations are compared with the calculated results on the equi-plastic strain surfaces.     

Combined stress waves with phase transition in thin-walled tubes简

The incremental constitutive relation and governing equations with combined stresses for phase transition wave propagation in a thin-walled tube are established based on the phase transition criterion considering both the hydrostatic pressure and the deviatoric stress. It is found that the centers of the initial and subsequent phase transition ellipses are shifted along the σ-axis in the στ-plane due to the tension-compression asymmetry induced by the hydrostatic pressure. The wave solution offers the "fast" and "slow" phase transition waves under combined longitudinal and torsional stresses in the phase transition region. The results show some new stress paths and wave structures in a thin-walled tube with phase transition, differing from those of conventional elastic-plastic materials.     

Thermo-mechanical measurement of elasto-plastic transitions during cyclic loading

The surface temperature of stainless steel SS304 low cycle fatigue specimens subjected to cyclic loading was studied using infrared thermography technique. The thermal data mapped onto the various stages of cyclic stress-strain curve shows the ability of these measurements to identify the yield points in both the compression and tension loading. Based on the results of this study, it is possible to identify the state of stress for materials such as elastic tension, plastic tension, elastic compression, plastic compression during cyclic loading using infrared thermographic data. The thermo-elastic slope and thermo-plastic slope was observed to be dependent on the prior loading cycles.     

Lüders bands propagation of 1045 steel under multiaxial stress state

Inhomogeneous plastic deformation of 1045 steel under monotonic loading was experimentally studied. Thin-walled tubular specimens were used in the experiments and custom-made small strain gages were bonded on the specimen surface to characterize the local deformation. Experiments were conducted under tension, torsion, and combined tension–torsion. During the propagation of Lüders bands, the local deformation experienced two-stage deformation: an abrupt plastic deformation stage followed by a slower deformation process. In some area of the gage section of the specimen, a small amount of initial plastic deformation occurred before the Lüders front reached. During the propagation of Lüders bands, multiple Lüders fronts can be formed. Under tension, torsion, and combined tension–torsion with a constant axial load, the Lüders front was approximately parallel to the material plane of maximum shear stress. When the combined axial-torsion followed a proportional fashion, the stress–extensometer strain responses were dependent on the axial/torsional loading ratio, and the Lüders fronts were oriented differently and propagated along the specimen axis at a different velocity. The local strain was inhomogeneous even at the work-hardening stage. The relationships between the equivalent stress and the equivalent plastic strain were found to be practically identical for all the loading cases studied.     

基于有限元模拟的SUS304奥氏体不锈钢摩擦耦合变形过程的应力分析

采用ANSYS/LS-DYNA软件对SUS 304奥氏体不锈钢薄板的摩擦耦合变形过程进行了数值模拟.采用隐式-显式序列求解法和分段线性塑性材料模型,分析了钢带摩擦耦合变形时的应力分布规律及载荷、下压量和滑动速度等因素对钢带剪应力、主应力及等效应力的影响.结果表明:摩擦耦合变形的试验参数显著影响钢带的应力分布,验证了钢带在低于其屈服强度的应力条件下发生塑性变形的摩擦诱发效应.对奥氏体不锈钢摩擦诱发马氏体转变行为的研究及其摩擦学性能的改善具有一定的指导意义.     

Dynamic Experiments using Simultaneous Compression and Shear Loading

Material characterization at high strain rates under simultaneous compression and shear loading has been a challenge due to the differing normal and shear wave speeds. An experimental technique utilizing the compression Kolsky bar apparatus was developed to apply dynamic compression and shear loading on a specimen nearly simultaneously. Synchronization between the compression and shear loading was realized by generating the torsion wave near the specimen which minimizes the time difference between the arrival of the compression and torsion waves. This modified Kolsky bar makes it possible to characterize the dynamic response of a material to combined compression and shear impact loading. This method can also be applied to study dynamic friction behavior across an interface under controlled loading conditions. The feasibility of this method is demonstrated in the dynamic characterization of a simulant polymer bonded explosive material.     

Some considerations on instability of combined loaded thin-walled tubes with a crack

Instability of a thin-walled stainless steel tube with a crack-shaped defect under combined loading is studied in this paper. Furthermore, the effects of the tube length, crack orientation, and crack length on the buckling behavior of tubes are investigated. The behavior of tubes subjected to combined is analyzed by using the finite element method (by Abaqus software). For cracked tubes with a fixed thickness, the buckling load decreases as the tube length and the ratio of the tube length to its diameter increase. Moreover, the buckling load of cracked tubes under combined loading also decreases with increasing crack length.     

Axial compression and energy absorption characteristics of high-strength thin-walled cylinders under impact load

Non-linear finite element software LS-DYNA is used to analyze the axial compression behavior and energy absorption of a high-strength thin-walled member under an impact load. To elucidate the effect of dynamic impact on the strain rate, the Cowper-Symonds equation is applied to analyze the plastic state of stress and the onset of dynamic yielding under different strain rates, such that the modeled deformation behavior of the member is consistent with the actual situation. Results for the thin-walled members made of mild steel and dual phase steel are compared. Assuming two different materials with equal sectional areas, an analysis confirms that the energy absorption of high-strength steel thin-walled component is better than the mild steel thin-walled component. Hence, thin-walled tubes made of high-strength steel are investigated using a series of analysis. The relationships between displacement and load, average load and energy absorption properties are obtained.