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A novel method for sports shoe testing based on a modified prosthetic foot test machine

Poster presented at International Calgary Running Symposium, August 14-17, 2014. Celebrating the Retirement of Dr. Benno M. Nigg
Eine neue Methode zur Testung von Sportschuhen mit Hilfe einer modifizierten Prothesenfuß-Testmaschine
: Starker, Felix; Blab, Florian; Dennerlein, Florian; Schneider, Urs

Poster urn:nbn:de:0011-n-3038669 (413 KByte PDF)
MD5 Fingerprint: 0cb4a89b459683e7c9be376f427e7038
Created on: 6.9.2014

2014, 1 pp.
International Calgary Running Symposium <1, 2014, Calgary>
Poster, Electronic Publication
Fraunhofer IPA ()
Bewegungsanalyse; Testen; ISO 22675; Prothesenfuß; Laufschuh; Sportschuh; Schuh; Medizintechnik; Biomechanik

The study determines the capability and adaption of a dynamic heel-to-toe walking endurance test for prosthetic feet (ISO 22675:2006) to mimic running kinetics and kinematics. The data used for this study was based on captured human running motion from a subject (m, 27 y, 72 kg) in a motion lab. A specific step was selected and processed to be feed into the test machine software. The test machine (Shore Western KS2-07) was modified for three dimensional motions and performed with a prosthetic foot model. A Qualisys motion capture system tracks the motion of the shoe as well as the machine. Forces and moments are acquired with a 6-DoF load cell. Furthermore machine sensor data (shank angle, axial height, acceleration, force) is recorded for comparison. The machine is force controlled and consequently adapts after several steps to the preferred force in shank direction (Fz). Other forces and moments are produced as results of the test setup. As stance time for heel-to-toe running was 0.24 s, the test was performed at different ratios (20% to 80%) of the real time motion to determine the capability of the machine controls to adapt to the motion. The test shows the capability of this approach to reproduce kinetics and kinematics of heel-to-toe running motion. At 60% of real time running speed (0.304 s stance time) forces and moments were reproducible. Based on initial results, machine performance relevant factors were analyzed (e.g. 3D-tilt table shape) to minimize hydraulic piston stroke and allow for the 3D motion.