论文信息 - Quasistatic to hypervelocity impactor loading of glass: autodyn hydrocode and static testing configurations

Quasistatic to hypervelocity impactor loading of glass: autodyn hydrocode and static testing configurations

Abstract Hypervelocity impact on glass leads to damage which involves both high pressure fluid dynamics (forming the “primary” crater) and comparatively low strain rate damage leading to spallation and extended platelet formation (conchoidal fracture). Conchoidal fracture may extend to much larger volumes than the primary crater and subsequently remove most or all of the primary crater. Understanding and modelling thus calls for knowledge of the equation of state, strength limits (both compressive and tensile) and, especially, crack propagation. We examine how a single improved hydrocode with Johnson Holmquist implementation in 2D and 3D can mimic both extremes of the impact process and look at how static test results compare to the hydrocode during the (conchoidal) stress relief by crack propagation at times very much greater than the final primary cratering phase.

J. A. M. McDonnell | D. J. Catling | M. K. Herbert | R. A. Clegg

[1] Colin J. Hayhurst,et al. Hydrocode modelling of hypervelocity impact on brittle materials : Depth of penetration and conchoidal diameter , 1999 .

[2] B. P. Denardo. MEASUREMENTS OF MOMENTUM TRANSFER FROM PLASTIC PROJECTILES TO MASSIVE ALUMINUM TARGETS AT SPEEDS UP TO 25,600 FEET PER SECOND , 1962 .

[3] J. McDonnell,et al. Morphological Classification of Impacts on the EURECA a Hubble Space Telescope Solar Arrays , 1997 .

[4] Simon F. Green,et al. The chemistry of micrometeoroid and space debris remnants captured on hubble space telescope solar cells , 2001 .

[5] Carl R. Maag,et al. OPTICAL SURVEY OF MICROMETEOROID AND SPACE DEBRIS IMPACT FEATURES ON EURECA , 1996 .

[6] A. B. Wenzel,et al. A review of explosive accelerators for hypervelocity impact , 1987 .

[7] Burton G. Cour-Palais,et al. Hypervelocity impact in metals, glass and composites , 1987 .