A length-adjustable vacuum-powered artificial muscle for wearable physiotherapy assistance in infants

Gollob, Samuel Dutra; Mendoza, Mijaíl Jaén; Koo, Bon Ho; Centeno, Esteban; Vela, Emir A.; Roche, Ellen T.

doi:10.3389/frobt.2023.1190387

Cited by 6 publications

(3 citation statements)

References 46 publications

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“…The field of soft robotics has opened up new avenues to design and fabricate actuators, sensors, and mechanisms ( Yasa et al, 2023 ). During the last decade, various actuation principles (e.g., pneumatic ( Xavier et al, 2022 ), dielectric ( Gupta et al, 2019 ), magnetorheological ( Bastola et al, 2020 ), magnetic ( Kim and Zhao, 2022 )) have motivated the development of soft actuators for a myriad of applications, ranging from aerospace to physiatry ( Huaroto et al, 2019 ; Yoo et al, 2019 ; Gollob et al, 2023 ; O’Neill et al, 2023 ; Zhang et al, 2023a ). In particular, soft pneumatic actuators have been the gold standard for creating large stroke actuation.…”

Section: Introductionmentioning

confidence: 99%

Leveraging pleat folds and soft compliant elements in inflatable fabric beams

Huaroto,

Suarez,

Kim

et al. 2024

Front. Robot. AI

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Inflatable fabric beams (IFBs) integrating pleat folds can generate complex motion by modifying the pleat characteristics (e.g., dimensions, orientations). However, the capability of the IFB to return to the folded configuration relies upon the elasticity of the fabrics, requiring additional pressure inputs or complementary mechanisms. Using soft compliant elements (SCEs) assembled onto pleat folds is an appealing approach to improving the IFB elasticity and providing a range of spatial configurations when pressurized. This study introduces an actuator comprising an IFB with pleat folds and SCEs. By methodologically assembling the SCEs onto the pleat folds, we constrain the IFB unfolding to achieve out-of-plane motion at 5 kPa. Besides, the proposed actuator can generate angular displacement by regulating the input pressure (> 5 kPa). A matrix-based representation and model are proposed to analyze the actuator motion. We experimentally study the actuator’s angular displacement by modifying SCE shapes, fold dimensions, and assembly distances of SCEs. Moreover, we analyze the effects of incorporating two SCEs onto a pleat fold. Our results show that the actuator motion can be tuned by integrating SCEs with different stiffness and varying the pleat fold dimensions. In addition, we demonstrate that the integration of two SCEs onto the pleat fold permits the actuator to return to its folded configuration when depressurized. In order to demonstrate the versatility of the proposed actuator, we devise and conduct experiments showcasing the implementation of a planar serial manipulator and a soft gripper with two grasping modalities.

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Section: Introductionmentioning

confidence: 99%

Leveraging pleat folds and soft compliant elements in inflatable fabric beams

Huaroto,

Suarez,

Kim

et al. 2024

Front. Robot. AI

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“…To this end, some research groups have focused their efforts on modifying the default motion of actuators through passive and active mechanisms, enabling mechanical programming after fabrication. However, these attempts are limited to manually change actuator’s length ( Gollob et al, 2022 ) or to modify the curvature radius in bending actuators such as replacing components of the soft pneumatic actuators as chambers ( Natividad et al, 2018 ), and reinforcements [flexible sleeves ( Galloway et al, 2013 ) and rigid shells ( Chen et al, 2017 )], as well as embedding smart materials as internal layers ( Firouzeh et al, 2015 ; Yoshida et al, 2018 ). A few studies have demonstrated promising results, creating multifunctional artificial muscles capable of producing omnidirectional bending ( Murali Babu et al, 2023 ), bending and pure contraction ( Lin et al, 2020 ) as well as 7 modes of operation ( Zhang et al, 2023 ).…”

Section: Introductionmentioning

confidence: 99%

Versatile vacuum-powered artificial muscles through replaceable external reinforcements

Mendoza,

Cancán,

Surichaqui

et al. 2024

Front. Robot. AI

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Soft pneumatic artificial muscles are a well actuation scheme in soft robotics due to its key features for robotic machines being safe, lightweight, and conformable. In this work, we present a versatile vacuum-powered artificial muscle (VPAM) with manually tunable output motion. We developed an artificial muscle that consists of a stack of air chambers that can use replaceable external reinforcements. Different modes of operation are achieved by assembling different reinforcements that constrain the output motion of the actuator during actuation. We designed replaceable external reinforcements to produce single motions such as twisting, bending, shearing and rotary. We then conducted a deformation and lifting force characterization for these motions. We demonstrated sophisticated motions and reusability of the artificial muscle in two soft machines with different modes of locomotion. Our results show that our VPAM is reusable and versatile producing a variety and sophisticated output motions if needed. This key feature specially benefits unpredicted workspaces that require a soft actuator that can be adjusted for other tasks. Our scheme has the potential to offer new strategies for locomotion in machines for underwater or terrestrial operation, and wearable devices with different modes of operation.

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“…Last yet importantly, their scalability feature makes devices comprising fabricbased bellow type actuators resonate well with the inherent need for a device focused on infant populations to adapt to fast growth. Indeed, as the infant develops and gains strength, the number of cells of the actuators can also be adjusted to provide the appropriate level of assistance, ensuring customized and progressive training [18], [28].…”

Section: Introductionmentioning

confidence: 99%

A Bidirectional Fabric-based Pneumatic Actuator for the Infant Shoulder: Design and Comparative Kinematic Analysis

Sahin

Dube

Mucchiani

et al. 2022

2022 31st IEEE International Conference on Robot and Human Interactive Communication (RO-MAN)

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This paper focuses on the design and systematic evaluation of fabric-based, bellow-type soft pneumatic actuators to assist with flexion and extension of the elbow, intended for use in infant wearable devices. Initially, the performance of a range of actuator variants was explored via simulation. The actuator variants were parameterized based on the shape, number, and size of the cells present. Subsequently, viable actuator variants identified from the simulations were fabricated and underwent further testing on a physical model based on an infant's body anthropometrics. The performance of these variants was evaluated based on kinematic analyses using metrics including movement smoothness, path length, and elbow joint angle. Internal pressure of the actuators was also attained. Taken together, results reported herein provide valuable insights about the suitability of several actuator designs to serve as components for pediatric wearable assistive devices.

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A length-adjustable vacuum-powered artificial muscle for wearable physiotherapy assistance in infants

Cited by 6 publications

References 46 publications

Leveraging pleat folds and soft compliant elements in inflatable fabric beams

Leveraging pleat folds and soft compliant elements in inflatable fabric beams

Versatile vacuum-powered artificial muscles through replaceable external reinforcements

A Bidirectional Fabric-based Pneumatic Actuator for the Infant Shoulder: Design and Comparative Kinematic Analysis

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