Study of "knee-thigh-hip" protection criterion

wbldb

Leung, Y. C.¹; Hue, B.¹; Fayon, A.¹; Tarrière, C.¹; Hamon, H.¹; Got, C.²; Patel, A.²; Hureau, J.³

Study of "knee-thigh-hip" protection criterion

Proceedings of the 27th Stapp Car Crash Conference

Affiliations

¹Laboratory of Physiology and Biomechanics, Peugeot-Renault Association, France

²I.R.B.A. Raymond Poincaré Hospital, Garches, France

³Faculty of Medicine, University of Paris, France
Abstract

A series of fresh human cadaver and Part 572 dummy tests was performed under different conditions which were comparable to those of real-world accidents. A European car model mounted on a sled was used; a pair of knee-targets was fixed directly to the car body in front of the passenger knees. Test conditions are summarized as follows: human-3-pt-belted cadaver with a sled impact velocity of 50 or 65 kph; 2-pt (thoracic)-belted-cadaver with a velocity of 65 kph, the legs being positioned normally or in an oblique manner.

Since the knee-thigh-hip tolerance is related to the shape and duration of the impact pulse, these interactions were the subject of a study.

The tolerance to fractures depends to a great extent on the subject's bone condition. In order to predict the risk of fracture for the whole population from the tolerance found in the tested subjects, studies of mineralization and bone strength were carried out on the compact-bone-sections taken from the femurs of the tested cadavers.

Tests were conducted also, using a Part 572 dummy, which enabled to predict a criterion for the knee-thigh-hip protection matched to this surrogate.

Discussion of similar attempts, such as F.I.C. (Femur Injury Criterion) and K.T.H.I.C. is included.
Links

DOI: 10.4271/831629

SAE: 831629

Cited By (17)

Year	Entry
1998	EEVC Working Group 17 Report: Improved Test Methods to Evaluate Pedestrian Protection Afforded by Passenger Cars. European Enhanced Vehicle-Safety Committee (EEVC); 1998.
1997	Crandall JR, Martin PG. Lower injuries sustained in crashes and corresponding biomechanical research. In: Proceedings of the International Symposum on Real World Crash Injury Research. 1997; Leicestershire, UK.
1989	Mertz HJ, Irwin AL, Melvin JW, Stalnaker RL, Beebe MS. Size, weight and biomechanical impact response requirements for adult size small female and large male dummies. In: Proceedings of the SAE International Congress & Exposition. February 27–March 3, 1989; Detroit, MI. Warrendale, PA: Society of Automotive Engineers. SAE 890756.
2015	Rupp JD. Knee, thigh, and hip injury biomechanics. In: Yoganandan N, Nahum AM, Melvin JW, eds. Accidental Injury: Biomechanics and Prevention. 3rd ed. New York: Springer; 2015:471-497.
1985	European Experimental Vehicle Committee. Pedestrian injury protection by car design. In: Proceedings of the 10th International Technical Conference on Experimental Safety Vehicles (ESV). July 1-4, 1985; Oxford, England.965-976. SAE 856112.
1989	Morgan RM, Eppinger RH, Marcus JH. Human cadaver patella-femur-pelvis injury due to dynamic frontal impact to the patella. In: Proceedings of the 12th International Technical Conference on Experimental Safety Vehicles (ESV). May 29–June 1, 1989; Göteborg, Sweden.683-698.
1986	Chamouard F, Tarriere C, Got C, Guillon F, Patel A, Hureau J. Relationship between some biomechanical and dimensional characteristics of the skull and the risk of cerebral injuries. In: Proceedings of the 1986 International IRCOBI Conference on the Biomechanics of Impact. September 2-4, 1986; Zurich, Switzerland.133-152.
1999	Banglmaier RF, Dvoracek-Driksna D, Oniang'o TE, Haut RC. Axial compressive load response of the 90° flexed human tibiofemoral joint. In: Proceedings of the 43rd Stapp Car Crash Conference. October 25-27, 1999; San Diego, CA. Warrendale, PA: Society of Automotive Engineers:127-139. SAE 99SC08.
2002	Rupp JD, Reed MP, Van Ee CA, Kuppa S, Wang SC, Goulet JA, Schneider LW. The tolerance of the human hip to dynamic knee loading. Stapp Car Crash J. 2002;46:211-228. SAE 2002-22-0011.
2003	Mertz HJ, Irwin AL, Prasad P. Biomechanical and scaling bases for frontal and side impact injury assessment reference values. Stapp Car Crash J. 2003;47:155-188. SAE 2003-22-0009.
2003	Rupp JD, Reed MP, Jeffreys TA, Schneider LW. Effects of hip posture on the frontal impact tolerance of the human hip joint. Stapp Car Crash J. 2003;47:21-33. SAE 2003-22-0002.
2008	Ruan JS, El-Jawahri R, Barbat S, Rouhana SW, Prasad P. Impact response and biomechanical analysis of the knee-thigh-hip complex in frontal impacts with a full human body finite element model. Stapp Car Crash J. 2008;52:505-526. SAE 2008-22-0019.
2008	Rupp JD, Miller CS, Reed MP, Madura NH, Klinich KD, Schneider LW. Characterization of knee-thigh-hip response in frontal impacts using biomechanical testing and computational simulations. Stapp Car Crash J. 2008;52:421-474. SAE 2008-22-0017.
2004	Rupp JD, Schneider LW. Injuries to the hip joint in frontal motor-vehicle crashes: biomechanical and real-world perspectives. Orthop Clin North Am. 2004;35(4):493-504.
2006	Salzar RS, Bass CRD, Kent R, Millington S, Davis M, Lucas S, Rudd R, Folk B, Donnellan L, Murakami D, Kobayashi S. Development of injury criteria for pelvic fracture in frontal crashes. Traffic Inj Prev. September 2006;7(3):299-305.
2006	Rupp JD. Biomechanics of Hip Injuries in Frontal Motor-Vehicle Crashes [PhD thesis]. Ann Arbor, MI: University of Michigan; 2006.
2009	Chang C-Y. Prediction of the Effects of Lower-Extremity Muscle Forces on Knee, Thigh, and Hip Injuries in Frontal Motor Vehicle Crashes [PhD thesis]. University of Michigan; 2009.