M. C. Yildirim, Ahmet Talha Kansizoglu, S. Emre, M. Derman, Sinan Coruk, A. Soliman, P. Şendur, B. Ugurlu
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Co-Ex: A Torque-Controllable Lower Body Exoskeleton for Dependable Human-Robot Co-existence
In this paper, we present our research study concerning the design and development of an exoskeleton that aims to provide 3D walking support with minimum number of actuators. Following a prior simulation study, the joint configuration was primarily determined. In order for the exoskeleton to possess advanced characteristics, the following design criteria were investigated: i) all the actuators (hip/knee/ankle) were deployed around the waist area to decrease leg weight and improve wearability, ii) custom-built series elastic actuators were used to power system for high fidelity torque-controllability, iii) 3D walking support is potentially enabled with reduced power requirements. As a result, we built the first actual prototype to experimentally verify the aforementioned design specifications. Furthermore, the preliminary torque control experiments indicated the viability of torque control.
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