Soft actuators hold great potential for applications in surgical operations, robotic manipulation, and prosthetic devices. However, they are limited by their structures, materials, and actuation methods, resulting in disadvantages in output force and dynamic response. This article introduces a soft pneumatic actuator capable of bending based on triangular prism origami. The origami creases are crafted by utilizing fabrics to gain swift response and fatigue-resistant properties. By connecting two actuators in series, combined motions including extension and diversified compound bending can be achieved, facilitating control in complex scenarios. After modularizing the soft actuator via mortise and tenon structures, several actuators can be programmed to execute a variety of intricate tasks by adjusting the timing sequences of their contraction and expansion. We showcase its applications in reconfigurable robots, and the results confirm that such a design is adequate for flexibly performing tasks such as soft gripping, navigational movement, and obstacle avoidance. These findings highlight the significance of our actuator in developing soft robots for versatile tasks.
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