Litcius/Paper detail

Self-Aligning Mechanism Improves Comfort and Performance With a Powered Knee Exoskeleton

Sergei V. Sarkisian, Marshall K. Ishmael, Tommaso Lenzi

2021IEEE Transactions on Neural Systems and Rehabilitation Engineering109 citationsDOIOpen Access PDF

Abstract

Misalignments between powered exoskeleton joints and the user's anatomical joints are inevitable due to difficulty locating the anatomical joint axis, non-constant location of the anatomical joint axis, and soft-tissue deformations. Self-aligning mechanisms have been proposed to prevent spurious forces and torques on the user's limb due to misalignments. Several exoskeletons have been developed with self-aligning mechanisms based on theoretical models. However, there is no experimental evidence demonstrating the efficacy of self-aligning mechanisms in lower-limb exoskeletons. Here we show that a lightweight and compact self-aligning mechanism improves the user's comfort and performance while using a powered knee exoskeleton. Experiments were conducted with 14 able-bodied subjects with the self-aligning mechanism locked and unlocked. Our results demonstrate up to 15.3% increased comfort and 38% improved performance when the self-aligning mechanism was unlocked. Not surprisingly, the spurious forces and torques were reduced by up to 97% when the self-aligning mechanism was unlocked. This study demonstrates the efficacy of self-aligning mechanisms in improving comfort and performance for sit-to-stand and position tracking tasks with a powered knee exoskeleton.

Topics & Concepts

ExoskeletonMechanism (biology)TorqueComputer scienceSpurious relationshipSimulationPowered exoskeletonKnee JointJoint (building)KinematicsEngineeringStructural engineeringPhysicsMedicineThermodynamicsQuantum mechanicsSurgeryClassical mechanicsMachine learningProsthetics and Rehabilitation RoboticsStroke Rehabilitation and RecoveryMuscle activation and electromyography studies