The effects of variable helmet weight and subject bracing on neck loading during frontal -Gx impact

Doczy, Erica; Mosher, Steve; Buhrman, John

Affiliations

¹Advanced Information Engineering Services, A General Dynamics Company, Dayton, OH

Abstract

Helmet-mounted systems (HMS), such as night vision goggles and helmet-mounted displays, are designed to enhance pilot performance. Using HMS, however, may also affect pilot safety by increasing the potential for neck injury during ejection due to the increase in dynamic forces generated in the cervical spine as a result of the change in helmet inertial properties. Pilot bracing techniques may also have an effect on ejection injury risk by allowing some of the neck forces to be off-loaded during the acceleration impact phases. A series of tests were conducted on the AFRL/HEPA Horizontal Impulse Accelerator (HIA) using human subjects to investigate the effects of helmet inertial properties and bracing techniques on human response to short-duration frontal impacts of variable magnitude. Head accelerations were measured and neck loads and moments were calculated to compare the head and neck responses using helmets of varying weight. Headrest loads were recorded to monitor and evaluate subject bracing. The neck loads and helmet weights were also extrapolated to higher levels in order to estimate injury thresholds for pilots wearing even heavier helmets at maximum seat accelerations. The results of this study will be used to establish head/neck injury criteria for helmet-mounted systems and to improve bracing techniques to minimize pilot injury during ejections.

Links

URL: http://www.dtic.mil/cgi-bin/GetTRDoc?AD=ADA446621

Cited Works (3)

Year	Entry
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2003	Perry CE, Buhrman JR, Doczy EJ, Mosher SE. Evaluation of the Effects of Variable Helmet Weight on Human Response During Lateral +Gy Impact. Wright-Patterson AFB, OH: Biomechanics Branch, Biosciences and Protection Division, Human Effectiveness Directorate, Air Force Research Laboratory; August 2003. Report No. AFRL-HE-WP-TR-2004-0013.
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Cited By (5)

Year	Entry
2011	Barker DJ, Albery C. Neck Fatigue and Comfort Effects Due to the Extended Wear of Law Enforcement Representative Head-Borne Personal Protective Equipment. Aberdeen Proving Ground, MD: Development And Engineering Command, U.S. Army Research, Chemical Biological Center, Edgewood; July 2011. Report No. ECBC-TR-825.
2011	Cote M, Buhrman J, Bridges N, Pirnstill C, Burneka C, Plaga J, Roush G. Establishment of Maximum Voluntary Compressive Neck Tolerance Levels. Wright-Patterson AFB, OH: Biomechanics Branch, Biosciences and Protection Division, Human Effectiveness Directorate, 711th Human Performance Wing, Air Force Research Laboratory; July 2011. Report No. AFRL-RH-WP-TR-2011-0090.
2008	Gallagher HL, Caldwell E, Albery CB. Neck Muscle Fatigue Resulting from Prolonged Wear of Weighted Helmets. Wright-Patterson AFB, OH: Biomechanics Branch, Biosciences and Protection Division, Human Effectiveness Directorate, Air Force Research Laboratory; June 2008. Report No. AFRL-RH-WP-TR-2008-0096.
2012	Parr JC, Miller ME, Bridges NR, Buhrman JR, Perry CE, Wright NL. Evaluation of the Nᵢⱼ neck injury criteria with human response data for use in future research on helmet mounted display mass properties. In: Proceedings of the Human Factors and Ergonomics Society 56th Annual Meeting. 2012:2070-2074.
2013	Newby N, Somers JT, Caldwell EE, Perry C, Littell J, Gernhardt M. Assessing biofidelity of the test device for human occupant restraint (THOR) against historic human volunteer data. Stapp Car Crash J. November 2013;57:469-505.