Thoracic response to shoulder belt loading: comparison of tabletop and frontal sled tests with PMHS

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Salzar, R. S.¹; Lau, S. H.¹; Lessley, D. J.¹; Sochor, M. R.²; Shaw, C. G.¹; Kent, R. W.¹; Crandall, J. R.¹

Thoracic response to shoulder belt loading: comparison of tabletop and frontal sled tests with PMHS

Traffic Inj Prev. 2013;14(2):159-167

© Taylor & Francis Group, LLC

Affiliations

¹Center for Applied Biomechanics, University of Virginia, Charlottesville, Virginia

²Department of Emergency Medicine, University of Virginia, Charlottesville, Virginia
Abstract and keywords

Objective: The recent refinement of high-rate optical tracking allows dramatically detailed thoracic deformation measurements to be taken during postmortem human subject (PMHS) sled tests. These data allow analysis of restraint belt geometry and the 3- dimensional thoracic deformations generated by belt impingement. One consequence of this new capability is a better understanding of complementary thoracic characterization experiments such as tabletop tests and how the thoracic response can be interpreted for applications involving more complex loading mechanisms.

Methods: This article reports a detailed evaluation of the timing, magnitude, and direction of the applied belt forces and the resulting thoracic deformations in 2 previously performed tests series involving frontal sled tests and tabletop belt-loading tests.

Results: In the sled tests, the posteriorly directed component (SAE x) of the belt tension (F_B) was F_Bx = 0.70 F_B at the shoulder but only F_Bx = 0.14 F_B where the belt engaged the anterolateral torso inferiorly. The corresponding components on the tabletop were F_Bx = 0.60 F_B (shoulder) and F_Bx = 0.48 F_B (lower).

Conclusions: When these components are cross-plotted with chest deflection, pronounced consequences of thoracic anterior wall deformation patterns due to flexion of the thoracic spine and the internal viscera’s inertia can be seen in the effective thoracic stiffness. Supplemental materials are available for this article. Go to the publisher’s online edition of Traffic Injury Prevention to view the supplemental file.

Keywords: deformation, geometry, models, safety belts, thorax
Links

DOI: 10.1080/15389588.2012.692223

PubMed: 23343025

WoS: 000314208600007
History

Received: 2012-03-14

Accepted: 2012-05-04

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2013	Perz R, Toczyski J, Kindig M, Ito D, Ejima S, Kamiji K, Yasuki T, Crandall J, Subit D. Evaluation of the geometrical properties distribution along the human ribs using different X‐ray imaging methods. In: Proceedings of the 2013 International IRCOBI Conference on the Biomechanics of Injury. September 11-13, 2013; Gothenburg, Sweden.245-256.
2015	Kim J, Lee I, Kim T, Kim H. Validation of abdominal characteristics under lap‐belt loadings using human body model morphed to an obese female. In: Proceedings of the 2015 International IRCOBI Conference on the Biomechanics of Injury. September 9-11, 2015; Lyon, France.133-135.
2022	Haverfield ZA, Hunter RL, Loftis KL, Agnew AM. Skeletal site and method-dependent variability of bone mineral density in injury biomechanics research. In: Proceedings of the 2022 International IRCOBI Conference on the Biomechanics of Injury. September 14-16, 2022; Porto, Portugal.332-360.
2022	Mühlbauer JA. Entwicklung regionaler Validierungsexperimente mit Freiwilligen für aktive Finite-Elemente Menschmodelle [PhD thesis]. Ludwig Maximilian University of Munich; 2022.