Predicting Perforation and Rupture of Composite Overwrapped Pressure Vessels following an Orbital Debris Particle Impact

摘要

Most spacecraft have at least one pressurized vessel on board. Because of the serious damage that might result following an on-orbit space debris particle impact, a primary design consideration is the anticipation and mitigation of that damage. While considerable effort has been expended in the study of flat unstressed spacecraft components under conditions intended to simulate those of a debris particle impact, numerous challenges have limited the testing conducted using pressurized elements, especially composite overwrapped pressure vessels (COPVs). To address this issue, a program was undertaken to characterize the hypervelocity impact response of COPVs. Depending on COPV design and impact / operating conditions, a COPV impacted at hypervelocity may experience either only relatively shallow damage; a through-hole, perhaps with localized liner cracking or composite peeling; or catastrophic failure (rupture). Whether or not a structural element is perforated is typically characterized by a ballistic limit equation (BLE). Similar to a BLE, a rupture limit equation (RLE) can be used to characterize whether or not rupture would occur following a perforating impact. Here we present the development of these two types of equations for COPVs impacted by hypervelocity particles. Data from over 50 impact tests on five different types of COPVs are pooled together and used in the development of the RLE and of the BLE. A comparison of the RLE and the BLE with experimental results shows that both equations are able to cleanly separate the regions of rupture from non-rupture, and perforation from non-perforation.