An experimental investigation of fracture response of aluminum 6061-T6 tubes under internal gaseous detonation loading has been carried out. The pressure load, with speeds exceeding 2 km/s, can be characterized as a pressure peak (ranging from 2 to 6 MPa) followed by an expansion wave. The unique combination of this particular traveling load and tube geometry produced fracture data not available before in the open literature. Experimental data of this type are useful for studying the fluid-structure-fracture interaction and various crack curving and branching phenomena, and also for validation for multi-physics and multi-scale modeling. Axial surface flaws were introduced to control the crack initiation site. Fracture threshold models were developed by combining a static fracture model and an extensively studied dynamic amplification factor for tubes under internal traveling loads. Experiments were also performed on hydrostatically loaded preflawed aluminum 6061-T6 tubes for comparison. Significantly different fracture behavior was observed and the difference was explained by fluid dynamics and energy considerations. The experiments yielded comparison on crack speeds, strain, and pressure histories. In other experiments, the specimens were also pre-torqued to control the propagation direction of the cracks. Measurements were made on the detonation velocity, strain history, blast pressure from the crack opening, and crack speeds. The curved crack paths were digitized. The Chapman-Jouguet pressure, initial axial flaw length, and torsion level were varied to obtain different crack patterns. The incipient crack kinking angle was found to be consistent with fracture under mixed-mode loading. High-speed movies of the fracture events and blast wave were taken and these were used in interpreting the quantitative data.Numerical simulations were performed using the commercial explicit finite-element software LS-Dyna. The detonation wave was modeled as a traveling boundary load. Both non-fracturing linear elastic simulations and elastoplastic simulations with fracture were conducted on three-dimensional models. The simulated fracture was compared directly with an experiment with the same conditions. The overall qualitative fracture behavior was captured by the simulation. The forward and backward cracks were observed to branch in both the experiment and simulation.
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机译:对铝6061-T6铝管在内部气体爆轰载荷作用下的断裂响应进行了实验研究。速度超过2 km / s的压力负载可以表征为压力峰值(2到6 MPa),然后是膨胀波。这种特殊的行进负载和管的几何形状的独特组合产生了在公开文献中以前无法获得的断裂数据。这种类型的实验数据可用于研究流体-结构-断裂相互作用以及各种裂缝弯曲和分支现象,还可用于多物理场和多尺度建模的验证。引入轴向表面缺陷以控制裂纹萌生部位。断裂阈值模型是通过将静态断裂模型与在内部行进载荷下广泛研究的管的动态放大系数相结合而开发的。为了进行比较,还对静水负载的预缺陷铝6061-T6管进行了实验。观察到明显不同的断裂行为,并且通过流体动力学和能量考虑因素解释了该差异。实验对裂纹速度,应变和压力历史进行了比较。在其他实验中,还对试样进行了预扭矩控制,以控制裂纹的传播方向。对爆震速度,应变历史,裂纹开口处的爆炸压力和裂纹速度进行了测量。弯曲的裂纹路径被数字化。改变查普曼-乔格压力,初始轴向缺陷长度和扭转水平以获得不同的裂纹模式。发现初始裂纹扭结角与混合模式载荷下的断裂一致。拍摄断裂事件和爆炸波的高速影像,并将其用于解释定量数据。使用商业的显式有限元软件LS-Dyna进行数值模拟。爆炸波被建模为行进边界载荷。在三维模型上进行了非断裂线性弹性模拟和具有断裂的弹塑性模拟。将模拟的裂缝直接与相同条件下的实验进行比较。通过模拟捕获了总体定性断裂行为。在实验和模拟中都观察到了向前和向后的裂纹分支。
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