To better protect Alpine skiers against injuries to both the lower leg and the knee, the objective of this work was to design a binding which: (1) maintained a consistent release level in twist in the presence of combined loads; (2) released the heelpiece based on the anterior/posterior (A/P) bending moment transmitted by the leg; and (3) modulated the release level in twist depending on the degree of contraction in muscles crossing the knee. To fulfill the objective, a conventional ski binding was modified. Modifications included integrating dynamometers into the toepiece, anti-friction device (AFD), and heelpiece. The toepiece sensor indicates the twisting moment while the AFD and heelpiece sensors indicate the anterior bending moment transmitted by the leg. To gain electronic control of binding release, a solenoid actuated mechanism was added which translated the heelpiece rearward along the ski to decouple the boot from the binding. Otherwise, the binding allowed normal mechanical function. Prototype testing confirmed the ability of the dynamometers to accurately measure desired loads in the presence of extraneous loads and the reliability of the solenoid actuated mechanism in releasing the hoot under loads typical of skiing. Thus, this work demonstrated the feasibility of hybrid electromechanical/mechanical releasable bindings. Such a demonstration should encourage the development of designs for commercial use.

Issue Section:
Design Innovation Papers
Topics:
Design, Dynamometers, Engineering prototypes, Friction, Knee, Muscle, Reliability, Sensors, Solenoids, Stress, Testing, Wounds
1.
ASTM, 1996, “Selection of Release Torque Values for Alpine Ski Bindings,” 1996 Annual Book of ASTM Standards Section 15, American Society for Testing and Materials, Philadelphia, PA, Vol. 15.07, ASTM Standard F939–93.
2.
Crawford, P., and Mote, C. D., Jr., 1996, “Fuzzy Logic Control of Bioadaptive Ski Binding Release,” Skiing Trauma and Safety: STP 1266, Mote, CD., Jr., Johnson, R. J., Hauser, W., and Schaff, P., eds., American Society for Testing and Materials, Philadelphia, PA, pp. 323–338.
3.
Greenwald, R. M., 1995, “Variations in Binding Release Torques Under Modified ASTM Testing Conditions Using a Static Preload Torque,” 11th International Symposium on Skiing Trauma and Safety, Voss, Norway, April 1995.
4.
Hull, M. L., and Johnson, C, 1989, “Axial Rotation of the Lower Limb Under Torsional Loading: I. Static and Dynamic Measurements in Vivo,” Skiing Trauma and Safety: STP 1022, American Society for Testing and Materials, Philadelphia, PA, pp. 277-290.
5.
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7.
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8.
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11.
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13.
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14.
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