TY - GEN
T1 - Modeling on propagation of shock waves induced by hypervelocity impact (HVI) with application to evaluation of HVI damage
AU - Liu, Menglong
AU - Su, Zhongqing
AU - Zhang, Qingming
AU - Long, Renrong
N1 - Publisher Copyright:
Copyright © 2015 by DEStech Publications, Inc. All rights re served.
PY - 2015
Y1 - 2015
N2 - A hypervelocity impact (HVI) of an aluminium sphere into an aluminium plate with a speed around 4000 m/s is numerically modeled and experimentally verified. Ubiquitous in outer space and significantly different from low velocity impact (LVI), HVI features transient, localized, and extreme material deformation in an adiabatic process, under which the induced shock waves present unique yet complex features. To numerically study this normal HVI phenomenon, a dedicated hybrid modeling combining the three-dimensional smooth-particle hydrodynamics (SPH) with the finite element analysis was developed, to gain an insight into characteristics of HVI-induced shock wave propagation. The effectiveness and accuracy of the modeling and simulation was demonstrated through quantitative coincidence in results between simulation and HVI experiment. Shock wave signal features on both time and frequency domain are analyzed intensively based on the theoretical model of HVI. Upon understanding the characteristics of HVI-induced shock waves, an acoustic emission (AE) based characterization strategy, targeting HVI-committed damage, was subsequently established using an enhanced delay-and-sum-based diagnostic imaging algorithm, and this strategy was validated by locating orbital debris-induced penetration in space structures, showing precise identification results.
AB - A hypervelocity impact (HVI) of an aluminium sphere into an aluminium plate with a speed around 4000 m/s is numerically modeled and experimentally verified. Ubiquitous in outer space and significantly different from low velocity impact (LVI), HVI features transient, localized, and extreme material deformation in an adiabatic process, under which the induced shock waves present unique yet complex features. To numerically study this normal HVI phenomenon, a dedicated hybrid modeling combining the three-dimensional smooth-particle hydrodynamics (SPH) with the finite element analysis was developed, to gain an insight into characteristics of HVI-induced shock wave propagation. The effectiveness and accuracy of the modeling and simulation was demonstrated through quantitative coincidence in results between simulation and HVI experiment. Shock wave signal features on both time and frequency domain are analyzed intensively based on the theoretical model of HVI. Upon understanding the characteristics of HVI-induced shock waves, an acoustic emission (AE) based characterization strategy, targeting HVI-committed damage, was subsequently established using an enhanced delay-and-sum-based diagnostic imaging algorithm, and this strategy was validated by locating orbital debris-induced penetration in space structures, showing precise identification results.
UR - http://www.scopus.com/inward/record.url?scp=84945537338&partnerID=8YFLogxK
U2 - 10.12783/shm2015/193
DO - 10.12783/shm2015/193
M3 - Conference contribution
AN - SCOPUS:84945537338
T3 - Structural Health Monitoring 2015: System Reliability for Verification and Implementation - Proceedings of the 10th International Workshop on Structural Health Monitoring, IWSHM 2015
SP - 1540
EP - 1547
BT - Structural Health Monitoring 2015
A2 - Chang, Fu-Kuo
A2 - Kopsaftopoulos, Fotis
PB - DEStech Publications
T2 - 10th International Workshop on Structural Health Monitoring: System Reliability for Verification and Implementation, IWSHM 2015
Y2 - 1 September 2015 through 3 September 2015
ER -