Soft Fibrous Syringe Architecture for Electricity‐Free and Motorless Control of Flexible Robotic Systems

Flexible robotic systems (FRSs) and wearable user interfaces (WUIs) have been widely used in medical fields, offering lower infection risk and shorter recovery, and supporting amiable human–machine interactions (HMIs). Recently, soft electric, thermal, magnetic, and fluidic actuators with enhanced safety and compliance have innovatively boosted the use of FRSs and WUIs across many sectors. Among them, soft hydraulic actuators offer great speed, low noise, and high force density. However, they currently require bulky electric motors/pumps, pistons, valves, rigid accessories, and complex controllers, which inherently result in high cost, low adaptation, and complex setups. This paper introduces a novel soft fibrous syringe architecture (SFSA) consisting of two or more hydraulically connected soft artificial muscles that enable electricity‐free actuation, motorless control, and built‐in sensing ability for use in FRSs and WUIs. Its capabilities are experimentally demonstrated with various robotic applications including teleoperated flexible catheters, cable‐driven continuum robotic arms, and WUIs. In addition, its sensing abilities to detect passive and active touch, surface texture, and object stiffness are also proven. These excellent results demonstrate a high feasibility of using a current‐free and motor‐less control approach for the FRSs and WUIs, enabling new methods of sensing and actuation across the robotic field. A novel electricity‐free, motorless, master–slave control methodology—soft fibrous syringe architecture—is presented. This mechanism converts the input motion from the master to the slave without the need for complex mechatronic systems, through hydraulic coupling of artificial muscles, which offers built‐in sensing capabilities. It can be applied to wearable devices and surgical systems where simplicity and miniaturization are necessary.