TY - GEN
T1 - MODELING OF SCHUBERTH HELMET UNDER BALLISTIC IMPACT FOR HEAD INJURY ASSESSMENT
AU - Nsiampa, N.
AU - Coghe, F.
N1 - Publisher Copyright:
© 2025 by International Ballistics Society All rights re served
PY - 2025
Y1 - 2025
N2 - A finite element model is developed to simulate the ballistic performance of the Schuberth helmet under 9x19 mm FMJ (Full Metal Jacket) bullet impact. The Schuberth helmet is a poly-aramid composite helmet, manufactured by Schuberth, formerly used by the Belgian Army as personal protection equipment. The model is validated on the basis of experimental data obtained during tests carried out within the Department of Weapon Systems and Ballistics (ABAL) of the Royal military Academy (RMA) using helmets of the same size at four different locations (front, left and right and crown). The metrics used for the model validation are the maximum Back Face Deflection (BFD) and the deflection time curves corresponding to the helmet back face dynamics. The Digital Image Correlation (DIC) technique is used for this purpose. Results show good agreement between numerical and experimental data. The validated model is then applied to simulate ballistic impacts on the Schuberth helmet mounted on an in-house head finite element head model to further investigate the risk of Behind Helmet Blunt Trauma.
AB - A finite element model is developed to simulate the ballistic performance of the Schuberth helmet under 9x19 mm FMJ (Full Metal Jacket) bullet impact. The Schuberth helmet is a poly-aramid composite helmet, manufactured by Schuberth, formerly used by the Belgian Army as personal protection equipment. The model is validated on the basis of experimental data obtained during tests carried out within the Department of Weapon Systems and Ballistics (ABAL) of the Royal military Academy (RMA) using helmets of the same size at four different locations (front, left and right and crown). The metrics used for the model validation are the maximum Back Face Deflection (BFD) and the deflection time curves corresponding to the helmet back face dynamics. The Digital Image Correlation (DIC) technique is used for this purpose. Results show good agreement between numerical and experimental data. The validated model is then applied to simulate ballistic impacts on the Schuberth helmet mounted on an in-house head finite element head model to further investigate the risk of Behind Helmet Blunt Trauma.
UR - https://www.scopus.com/pages/publications/105010295680
U2 - 10.12783/ballistics25/37224
DO - 10.12783/ballistics25/37224
M3 - Conference contribution
AN - SCOPUS:105010295680
T3 - Proceedings - 34th International Symposium on Ballistics, BALLISTICS 2025
SP - 1479
EP - 1487
BT - Proceedings - 34th International Symposium on Ballistics, BALLISTICS 2025
A2 - Carlucci, Don
A2 - Uhlig, W. Casey
PB - DEStech Publications
T2 - 34th International Symposium on Ballistics, BALLISTICS 2025
Y2 - 19 May 2025 through 23 May 2025
ER -