Source-Free Bistable Fluidic Gripper for Size-Selective and Stiffness-Adaptive Grasping
This work addresses the portability and autonomy limitations of conventional fluid-driven soft grippers by eliminating external sources, offering a compact solution for underwater and field manipulation.
The paper introduces a self-contained soft gripper that uses internal liquid redistribution among bistable chambers to achieve size-selective and stiffness-adaptive grasping without external power, enabling stable grasping with passive adaptation to object stiffness.
Conventional fluid-driven soft grippers typically depend on external sources, which limit portability and long-term autonomy. This work introduces a self-contained soft gripper with fixed size that operates solely through internal liquid redistribution among three interconnected bistable snap-through chambers. When the top sensing chamber deforms upon contact, the displaced liquid triggers snap-through expansion of the grasping chambers, enabling stable and size-selective grasping without continuous energy input. The internal hydraulic feedback further allows passive adaptation of gripping pressure to object stiffness. This source-free and compact design opens new possibilities for lightweight, stiffness-adaptive fluid-driven manipulation in soft robotics, providing a feasible approach for targeted size-specific sampling and operation in underwater and field environments.