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During high-speed rear impacts with delta-V > 25 km/h, the front seats may rotate rearward due to occupant and seat momentum change leading to possibly large seat deflection. One possible way of limiting this may be by introducing a structure that would restrict large rotations or deformations, however, such a structure would change the front seat occupant kinematics and kinetics. The goal of this study was to understand the influence of seat back restriction on head, neck and torso responses of front seat occupants when subjected to a moderate speed rear-impact. This was done by simulating a rear impact scenario with a delta-V of 37.4 km/h using LS-Dyna, with the GHBMC M50 occupant model and a manufacturer provided seat model. The study included two parts, the first part was to identify worst case scenarios using the simplified GHBMC M50-OS, and the second part was to further investigate the identified scenarios using the detailed GHBMC M50-O.

The deformation behavior of mild steels was discussed through analyzing a typical stress-strain curve obtained from standard tension tests. Material parameters were calculated from the stress-strain curve and a power-law model was developed for this typical mild steel. Based on the calculated material parameters, material property change with pre-deformation was studied and new stress-strain curves were developed for this mild steel after different pre-deformation. A rectangular tube model related to different pre-deformation magnitudes was created using LS-DYNA. The deformation behavior of this rectangular tube under four different basic loading conditions - tension, compression, bending, and torsion - was investigated through finite element analyses. The variation of internal energy and reaction force with the magnitude of pre-deformation and subsequent structural deformation was studied.