Transient Opening of the Mitochondrial Permeability Transition Pore Induces Microdomain Calcium Transients in Astrocyte Processes

In this article, we have proposed a novel robotic finger design principle aimed to address two challenges in soft pneumatic grippers-the controllability of the stiffness and the controllability of the bending position. The proposed finger design is composed of a 3D printed multimaterial substrate and a soft pneumatic actuator. The substrate has four polylactic acid (PLA) segments interlocked with three shape memory polymer (SMP) joints, inspired by bones and joints in human fingers. By controlling the thermal energy of an SMP joint, the stiffness of the joints is modulated due to the dramatic change in SMP elastic modulus around its glass transition temperature (T). When SMP joints are heated above T, they exhibit very small stiffness, allowing the finger to easily bend around the SMP joints if the attached soft actuator is actuated. When there is no force from the soft actuator, shape recovery stress in SMP contributes to the finger's shape restoration. Since each joint's rotation can be individually controlled, the position control of the finger is made possible. Experimental analysis has been conducted to show the finger's variable stiffness and the result is compared with the analytical values. It is found that the stiffness ratio can be 24.9 times for a joint at room temperature (20°C) and at an elevated temperature of 60°C when air pressure p of the soft actuator is turned off. Finally, a gripper composed of two fingers is fabricated for demonstration.

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Principles and methods for stiffness modulation in soft robot design and development

Yang

Chen

2018

Bio-des. Manuf.

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Compared to traditional rigid robots, soft robots, primarily made of deformable, or less rigid materials, have good adaptability, conformability and safety in interacting with the environment. Although soft robots have shown great potentials for extended applications and possibilities that are impossible or difficult for rigid body robots, it is of great importance for them to have the capability of controllable stiffness modulation. Stiffness modulation allows soft robots to have reversible change between the compliant, or flexible state and the rigid state. In this paper, we summarize existing principles and methods for stiffness modulation in soft robotic development and divide them into four groups based on their working principles. Acoustic-based methods have been proposed as the potential fifth group in stiffness modulation of soft robots. Initial design proposals based on the proposed acoustic method are presented, and challenges in further development are highlighted.

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Hybrid Jamming for Bioinspired Soft Robotic Fingers

et al. 2020

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Soft Robotic Grippers Based on Particle Transmission

Chen

Yang

et al. 2019

IEEE/ASME Trans. Mechatron.

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Innovative Design of Embedded Pressure and Position Sensors for Soft Actuators

Yang

Chen

2018

IEEE Robot. Autom. Lett.

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Yang Yang

Controllable and reversible tuning of material rigidity for robot applications

A Novel, Variable Stiffness Robotic Gripper Based on Integrated Soft Actuating and Particle Jamming

Passive Particle Jamming and Its Stiffening of Soft Robotic Grippers

Bioinspired Robotic Fingers Based on Pneumatic Actuator and 3D Printing of Smart Material

Principles and methods for stiffness modulation in soft robot design and development

Hybrid Jamming for Bioinspired Soft Robotic Fingers

Soft Robotic Grippers Based on Particle Transmission

Innovative Design of Embedded Pressure and Position Sensors for Soft Actuators

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