TY - GEN
T1 - Damage mechanism of Aluminosilicate glass under low-velocity hard impact
T2 - 19th International Bhurban Conference on Applied Sciences and Technology, IBCAST 2022
AU - Raza, Muhammad Aamir
AU - Sheikh, Muhammad Zakir
AU - Atif, M.
AU - Li, Yuan
AU - Suo, Tao
N1 - Publisher Copyright:
© 2022 IEEE.
PY - 2022
Y1 - 2022
N2 - Aluminosilicate glass is increasingly finding applications in the defense and aerospace industry due to its superior impact-resistant properties. However, these products are inevitably prone to impact during their service, resulting in a catastrophic failure. Hence, it is cardinal to analyze the behavior of constituting glass elements under desired service conditions for rendering robust and efficient product design. This study is aimed to investigate the dynamic flexure behavior of Aluminosilicate glass under a three-point flexural configuration. Indigenously developed Electromagnetic Split Hopkinson Pressure Bar (ESHPB) was introduced. High-speed reprography was performed to evaluate the damage mechanism. It is elicited that stresses induced due to the bending on the tensile face of the specimen are the root cause of failure for low-velocity hard impact scenarios simulated in the study. Results of the experiments were numerically simulated in an explicit dynamic solver, and a calibrated Johnson-Holmquist (JH-2) model was employed as a material model. Systematic numerical evaluation of the JH-2 model revealed that peak failure stress is not mesh-dependent. Instead, the failure time monotonically decreases with the decrease in mesh size. It is established that under low-velocity hard impact scenarios, the proposed simulation algorithm can successfully mimic experimentally observed failure modes and stresses.
AB - Aluminosilicate glass is increasingly finding applications in the defense and aerospace industry due to its superior impact-resistant properties. However, these products are inevitably prone to impact during their service, resulting in a catastrophic failure. Hence, it is cardinal to analyze the behavior of constituting glass elements under desired service conditions for rendering robust and efficient product design. This study is aimed to investigate the dynamic flexure behavior of Aluminosilicate glass under a three-point flexural configuration. Indigenously developed Electromagnetic Split Hopkinson Pressure Bar (ESHPB) was introduced. High-speed reprography was performed to evaluate the damage mechanism. It is elicited that stresses induced due to the bending on the tensile face of the specimen are the root cause of failure for low-velocity hard impact scenarios simulated in the study. Results of the experiments were numerically simulated in an explicit dynamic solver, and a calibrated Johnson-Holmquist (JH-2) model was employed as a material model. Systematic numerical evaluation of the JH-2 model revealed that peak failure stress is not mesh-dependent. Instead, the failure time monotonically decreases with the decrease in mesh size. It is established that under low-velocity hard impact scenarios, the proposed simulation algorithm can successfully mimic experimentally observed failure modes and stresses.
KW - Aluminosilicate glass
KW - Brittle fracture
KW - Damage mechanism
KW - ESHPB
KW - Flexural strength
UR - http://www.scopus.com/inward/record.url?scp=85146491562&partnerID=8YFLogxK
U2 - 10.1109/IBCAST54850.2022.9990123
DO - 10.1109/IBCAST54850.2022.9990123
M3 - 会议稿件
AN - SCOPUS:85146491562
T3 - Proceedings of 2022 19th International Bhurban Conference on Applied Sciences and Technology, IBCAST 2022
SP - 82
EP - 87
BT - Proceedings of 2022 19th International Bhurban Conference on Applied Sciences and Technology, IBCAST 2022
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 16 August 2022 through 20 August 2022
ER -