A procedure has been developed to represent the loading on a penetrator and its motion during oblique penetration into geologic media. The penetrator is modeled with the explicit dynamics, finite element computer program PRONTO 3D and the coupled pressure on the penetrator is given in a new loading option based on a separate cavity expansion (CE) solution that accounts for the pressure reduction from a nearby target free surface. The free-surface influence distance is selected in a predictive manner by considering the pressure to expand a spherical cavity in a finite radius sphere of the target material. The CE/PRONTO 3D procedure allows a detailed description of the penetrator for predicting shock environments or structural failure during the entire penetra- tion event and is sufficiently rapid to be used in design optimization. It has been evaluated by comparing its results with data from two field tests of a full-scale penetrator into frozen soil at an impact angles of 49.6 and 52.5 degrees from the horizontal. The measured penetrator rotations were 24 and 22 degrees, respectively. In the simulation, the rotation was 21 degrees and predom- inately resulted from the pressure reduction of the free surface. Good agreement was also found for the penetration depth and axial and lateral acceleration at two locations in the penetrator.
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机译:已经开发出一种程序来表示穿透器的载荷及其在倾斜穿透地质介质过程中的运动。穿透器采用显式动力学建模,使用有限元计算机程序PRONTO 3D,并且基于单独的空腔扩展(CE)解决方案,通过新的加载选项提供了穿透器上的耦合压力,该解决方案可解决来自附近目标释放的压力降低表面。通过考虑在目标材料的有限半径球体内扩展球形腔的压力,以预测方式选择自由表面影响距离。 CE / PRONTO 3D程序可对穿透器进行详细描述,以预测整个穿透事件期间的冲击环境或结构破坏,并且速度足够快,可用于设计优化。通过将其结果与两次全尺寸穿透器在冰冻土壤中与水平面的撞击角为49.6和52.5度的实测数据进行比较,对它进行了评估。测得的穿透器旋转分别为24度和22度。在模拟中,旋转为21度,主要是由于自由表面的压力降低引起的。对于穿透器中两个位置的穿透深度以及轴向和横向加速度也发现了很好的一致性。
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