Title: Modelling and impact analysis of football player head with helmet toward mitigating brain concussion

Authors: Peyman Honarmandi; Ali M. Sadegh; Paul V. Cavallaro

Addresses: Department of Mechanical Engineering, The City College of the City University of New York (CUNY), New York, NY 10031, USA ' Department of Mechanical Engineering, The City College of the City University of New York (CUNY), New York, NY 10031, USA ' Department of Mechanical Engineering, The City College of the City University of New York (CUNY), New York, NY 10031, USA

Abstract: In recent years, increasing concussions among American football players have drawn attention and concerns regarding safety of today's football helmets. This study investigates the effects of concussive impact forces on the brain of football players and the shock absorbing performance of actual football helmets. Initially, the mechanical properties of typical helmet materials were obtained through compression tests and hysteresis loop experiments. Next, a lumped-mass model was developed to physically describe both the head and helmet together against an impact load, and the brain response was obtained from the semi-analytical analysis. To extract more information such as strains and wave propagations within the brain, a detailed continuum model was constructed and the response of the brain was analysed by using the finite element method. A realistic impact load was obtained from a case study of actual football play. Our experimental data along with biomechanical data of the head and brain from the available literature were incorporated into our modelling and analyses. The results indicated that the accelerations and strains in the brain were both above the concussion thresholds and that current football helmet designs may not protect players against concussion.

Keywords: American football players; football helmets; player safety; football helmet design; material characteristics; helmet materials; mechanical properties; foams; head modelling; helmet modelling; vibration analysis; head impact; traumatic brain injury; TBI; brain concussion; impact analysis; shock absorbtion; biomechanics; compression tests; hysteresis loop; lumped-mass models; impact load; strain; wave propagation; continuum models; finite element method; FEM.

DOI: 10.1504/IJECB.2015.074732

International Journal of Experimental and Computational Biomechanics, 2015 Vol.3 No.4, pp.267 - 299

Received: 08 Jun 2015
Accepted: 21 Aug 2015

Published online: 16 Feb 2016 *

Full-text access for editors Full-text access for subscribers Purchase this article Comment on this article