Machines that mimic humans have inspired scientists for centuries.Bioinspired soft robotic hands are a good example of such an endeavor,featuring intrinsic material compliance and continuous motion to deal with uncert...Machines that mimic humans have inspired scientists for centuries.Bioinspired soft robotic hands are a good example of such an endeavor,featuring intrinsic material compliance and continuous motion to deal with uncertainty and adapt to unstructured environments.Recent research led to impactful achievements in functional designs,modeling,fabrication,and control of soft robots.Nevertheless,the full realization of life-like movements is still challenging to achieve,often based on trial-and-error considerations from design to fabrication,consuming time and resources.In this study,a soft robotic hand is proposed,composed of soft actuator cores and an exoskeleton,featuring a multimaterial design aided by finite element analysis(FEA)to define the hand geometry and promote finger’s bendability.The actuators are fabricated using molding,and the exoskeleton is 3D-printed in a single step.An ON-OFF controller keeps the set fingers’inner pressures related to specific bending angles,even in the presence of leaks.The FEA numerical results were validated by experimental tests,as well as the ability of the hand to grasp objects with different shapes,weights,and sizes.This integrated solution will make soft robotic hands more available to people,at a reduced cost,avoiding the time-consuming design-fabrication trial-and-error processes.展开更多
Bio-inspired soft robots have already shown the ability to handle uncertainty and adapt to unstructured environments.However,their availability is partially restricted by time-consuming,costly,and highly supervised de...Bio-inspired soft robots have already shown the ability to handle uncertainty and adapt to unstructured environments.However,their availability is partially restricted by time-consuming,costly,and highly supervised design-fabrication processes,often based on resource-intensive iterative workflows.Here,we propose an integrated approach targeting the design and fabrication of pneumatic soft actuators in a single casting step.Molds and sacrificial water-soluble hollow cores are printed using fused filament fabrication.A heated water circuit accelerates the dissolution of the core’s material and guarantees its complete removal from the actuator walls,while the actuator’s mechanical operability is defined through finite element analysis.This enables the fabrication of actuators with non-uniform cross-sections under minimal supervision,thereby reducing the number of iterations necessary during the design and fabrication processes.Three actuators capable of bending and linear motion were designed,fabricated,integrated,and demonstrated as 3 different bio-inspired soft robots,an earthworm-inspired robot,a 4-legged robot,and a robotic gripper.We demonstrate the availability,versatility,and effectiveness of the proposed methods,contributing to accelerating the design and fabrication of soft robots.This study represents a step toward increasing the accessibility of soft robots to people at a lower cost.展开更多
基金supported by Portuguese national funds through FCT-Fundação para a Ciência e a Tecnologia(grant numbers UIDB/00285/2020,LA/P/0112/2020,and 2022.13512.BD).
文摘Machines that mimic humans have inspired scientists for centuries.Bioinspired soft robotic hands are a good example of such an endeavor,featuring intrinsic material compliance and continuous motion to deal with uncertainty and adapt to unstructured environments.Recent research led to impactful achievements in functional designs,modeling,fabrication,and control of soft robots.Nevertheless,the full realization of life-like movements is still challenging to achieve,often based on trial-and-error considerations from design to fabrication,consuming time and resources.In this study,a soft robotic hand is proposed,composed of soft actuator cores and an exoskeleton,featuring a multimaterial design aided by finite element analysis(FEA)to define the hand geometry and promote finger’s bendability.The actuators are fabricated using molding,and the exoskeleton is 3D-printed in a single step.An ON-OFF controller keeps the set fingers’inner pressures related to specific bending angles,even in the presence of leaks.The FEA numerical results were validated by experimental tests,as well as the ability of the hand to grasp objects with different shapes,weights,and sizes.This integrated solution will make soft robotic hands more available to people,at a reduced cost,avoiding the time-consuming design-fabrication trial-and-error processes.
基金supported by Portuguese national funds through FCT-Fundacao para a Ciencia e a Tecnologia,[grant numbers UIDB/00285/2020,LA/P/0112/2020,and 2022.13512.BD].
文摘Bio-inspired soft robots have already shown the ability to handle uncertainty and adapt to unstructured environments.However,their availability is partially restricted by time-consuming,costly,and highly supervised design-fabrication processes,often based on resource-intensive iterative workflows.Here,we propose an integrated approach targeting the design and fabrication of pneumatic soft actuators in a single casting step.Molds and sacrificial water-soluble hollow cores are printed using fused filament fabrication.A heated water circuit accelerates the dissolution of the core’s material and guarantees its complete removal from the actuator walls,while the actuator’s mechanical operability is defined through finite element analysis.This enables the fabrication of actuators with non-uniform cross-sections under minimal supervision,thereby reducing the number of iterations necessary during the design and fabrication processes.Three actuators capable of bending and linear motion were designed,fabricated,integrated,and demonstrated as 3 different bio-inspired soft robots,an earthworm-inspired robot,a 4-legged robot,and a robotic gripper.We demonstrate the availability,versatility,and effectiveness of the proposed methods,contributing to accelerating the design and fabrication of soft robots.This study represents a step toward increasing the accessibility of soft robots to people at a lower cost.
