TY - JOUR
T1 - A length-adjustable vacuum-powered artificial muscle for wearable physiotherapy assistance in infants
AU - Gollob, Samuel Dutra
AU - Mendoza, Mijaíl Jaén
AU - Koo, Bon Ho Brandon
AU - Centeno, Esteban
AU - Vela, Emir A.
AU - Roche, Ellen T.
N1 - Publisher Copyright:
Copyright © 2023 Gollob, Mendoza, Koo, Centeno, Vela and Roche.
PY - 2023
Y1 - 2023
N2 - Soft pneumatic artificial muscles are increasingly popular in the field of soft robotics due to their light-weight, complex motions, and safe interfacing with humans. In this paper, we present a Vacuum-Powered Artificial Muscle (VPAM) with an adjustable operating length that offers adaptability throughout its use, particularly in settings with variable workspaces. To achieve the adjustable operating length, we designed the VPAM with a modular structure consisting of cells that can be clipped in a collapsed state and unclipped as desired. We then conducted a case study in infant physical therapy to demonstrate the capabilities of our actuator. We developed a dynamic model of the device and a model-informed open-loop control system, and validated their accuracy in a simulated patient setup. Our results showed that the VPAM maintains its performance as it grows. This is crucial in applications such as infant physical therapy where the device must adapt to the growth of the patient during a 6-month treatment regime without actuator replacement. The ability to adjust the length of the VPAM on demand offers a significant advantage over traditional fixed-length actuators, making it a promising solution for soft robotics. This actuator has potential for various applications that can leverage on demand expansion and shrinking, including exoskeletons, wearable devices, medical robots, and exploration robots.
AB - Soft pneumatic artificial muscles are increasingly popular in the field of soft robotics due to their light-weight, complex motions, and safe interfacing with humans. In this paper, we present a Vacuum-Powered Artificial Muscle (VPAM) with an adjustable operating length that offers adaptability throughout its use, particularly in settings with variable workspaces. To achieve the adjustable operating length, we designed the VPAM with a modular structure consisting of cells that can be clipped in a collapsed state and unclipped as desired. We then conducted a case study in infant physical therapy to demonstrate the capabilities of our actuator. We developed a dynamic model of the device and a model-informed open-loop control system, and validated their accuracy in a simulated patient setup. Our results showed that the VPAM maintains its performance as it grows. This is crucial in applications such as infant physical therapy where the device must adapt to the growth of the patient during a 6-month treatment regime without actuator replacement. The ability to adjust the length of the VPAM on demand offers a significant advantage over traditional fixed-length actuators, making it a promising solution for soft robotics. This actuator has potential for various applications that can leverage on demand expansion and shrinking, including exoskeletons, wearable devices, medical robots, and exploration robots.
KW - adaptable
KW - artificial muscle
KW - growing
KW - soft robotics
KW - wearable
UR - http://www.scopus.com/inward/record.url?scp=85159882939&partnerID=8YFLogxK
U2 - 10.3389/frobt.2023.1190387
DO - 10.3389/frobt.2023.1190387
M3 - Article
C2 - 37213243
AN - SCOPUS:85159882939
SN - 2296-9144
VL - 10
JO - Frontiers in Robotics and AI
JF - Frontiers in Robotics and AI
M1 - 1190387
ER -