posted on 2019-03-06, 09:38authored byChristian Di Natali, Tommaso Poliero, Matteo Sposito, Eveline Graf, Christoph Bauer, Carole Pauli, Eliza Bottenberg, Adam de Eyto, Leonard O'SullivanLeonard O'Sullivan, Andrés F. Hidalgo, Daniel Scherly, Konrad S. Stadler, Darwin G. Caldwell, Jesús Ortiz
Wearable devices are fast evolving to address mobility and autonomy needs of elderly people who
would benefit from physical assistance. Recent developments in soft robotics provide important
opportunities to develop soft exoskeletons (also called exosuits) to enable both physical assistance
and improved usability and acceptance for users. The XoSoft EU project has developed a modular
soft lower limb exoskeleton to assist people with low mobility impairments. In this paper, we present
the design of a soft modular lower limb exoskeleton to improve person’s mobility, contributing to
independence and enhancing quality of life. The novelty of this work is the integration of quasipassive
elements in a soft exoskeleton. The exoskeleton provides mechanical assistance for subjects
with low mobility impairments reducing energy requirements between 10% and 20%. Investigation
of different control strategies based on gait segmentation and actuation elements is presented. A first
hip–knee unilateral prototype is described, developed, and its performance assessed on a post-stroke
patient for straight walking. The study presents an analysis of the human–exoskeleton energy patterns
by way of the task-based biological power generation. The resultant assistance, in terms of
power, was 10.9%± 2.2% for hip actuation and 9.3%± 3.5% for knee actuation. The control strategy
improved the gait and postural patterns by increasing joint angles and foot clearance at specific
phases of the walking cycle.
Funding
Study on Aerodynamic Characteristics Control of Slender Body Using Active Flow Control Technique