Songwen Jiang scite author profile

In complex systems like aircraft engines and oil refinery machines, pipeline inspection is an essential task for ensuring safety. Here, we proposed a type of smart material–driven pipeline inspection robot (weight, 2.2 grams; length, 47 millimeters; diameter, <10 millimeters) that could fit into pipes with sub-centimeter diameters and different curvatures. We adopted high–power density, long-life dielectric elastomer actuators as artificial muscles and smart composite microstructure–based, high-efficiency anchoring units as transmissions. Fast assembling of components using magnets with an adjustable number of units was used to fit varying pipeline geometries. We analyzed the dynamic characteristics of the robots by considering soft material’s unique properties like viscoelasticity and dynamic vibrations and tuned the activation voltage’s frequency and phase accordingly. Powered by tethered cables from outside the pipe, our peristaltic pipeline robot achieved rapid motions horizontally and vertically (horizontal: 1.19 body lengths per second, vertical: 1.08 body lengths per second) in a subcentimeter-sized pipe (diameter, 9.8 millimeters). Besides, it was capable of moving in pipes with varying geometries (diameter-changing pipe, L-shaped pipe, S-shaped pipe, or spiral-shaped pipe), filled media (air or oil), and materials (glass, metal, or carbon fiber). To demonstrate its capability for pipeline inspection, we installed a miniature camera on its front and controlled the robot manually from outside. The robot successfully finished an inspection task at different speeds.

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Long‐Life‐Cycle and Damage‐Recovery Artificial Muscles via Controllable and Observable Self‐Clearing Process

Jiang

Tang

Liu

et al. 2021

Adv Eng Mater

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Dielectric elastomer actuators (DEAs) exhibit a collection of excellent performances to be the next‐generation artificial muscles, yet they suffer from short lifespan and premature breakdown. Self‐clearing of defects from thin, compliant electrodes can potentially solve these problems, yet this process is currently neither observable nor controllable. Herein, a dimensionless indicator named capacitor retention is proposed to indicate the remaining capacity to generate force/displacement of a DEA during self‐clearing. This indicator can be conveniently monitored during the short‐term and long‐term degradation of the actuators with different configurations and different driving modes. Based on this indicator, DEAs’ dielectric strength is redefined. With the assistance of scalable manufacturing of multilayered DEAs, several key factors that affect the conditions under which the self‐clearing phenomena occur, as well as how they affect the dielectric strength of the actuators, are investigated. Finally, through self‐clearing preprocess, using appropriate combinations of factors derived from the earlier investigations, high‐performance DEAs with unidirectional strain of 9.4%, power density of 301 W kg−1, >1 million life cycles at a resonant frequency of 125 Hz, and the ability to recover from multiple times of external damages are achieved. This work can potentially produce long‐life and highly robust artificial muscles for DEAs’ future applications.

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Increasing the Payload and Terrain Adaptivity of an Untethered Crawling Robot Via Soft-Rigid Coupled Linear Actuators

Dong

Tang

Jiang

et al. 2021

IEEE Robot. Autom. Lett.

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SHUYU Robot: An Automatic Rapid Temperature Screening System

Gong

Jiang

Meng

et al. 2020

Chin. J. Mech. Eng.

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A Review on High‐Frequency Dielectric Elastomer Actuators: Materials, Dynamics, and Applications

Tang

Jiang

et al. 2023

Advanced Intelligent Systems

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Dielectric elastomer actuators (DEAs) as a typical class of electroactive polymers have been developed rapidly in the last two decades due to their advantages such as large strain, high energy density, and fast response. The high‐frequency characteristics of DEAs enable them to be applied in a wider range of fields. In this review, the high‐frequency (>10 Hz) characteristics and applications of DEAs are focused on. The basic concepts and metrics for high‐frequency DEAs are first given. Next, the commercial and synthesized dielectric and electrode materials of DEAs used in high‐frequency applications are reviewed. Following materials, strategies for extending the lifetime of DEAs are introduced. Subsequently, the dynamic modeling approaches for DEAs are presented, considering damping, inertia, and the electrical loss. Building on the fundamental research, some important applications are summarized based on the high‐frequency motions of DEAs including loudspeakers, active vibration suppression, pumps/valves, haptic devices, and high‐speed mobile robots. Finally, the conclusions and future perspectives are given. This review will give readers a clearer understanding of how to design and use high‐frequency DEAs.

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Songwen Jiang

A pipeline inspection robot for navigating tubular environments in the sub-centimeter scale

Long‐Life‐Cycle and Damage‐Recovery Artificial Muscles via Controllable and Observable Self‐Clearing Process

Increasing the Payload and Terrain Adaptivity of an Untethered Crawling Robot Via Soft-Rigid Coupled Linear Actuators

SHUYU Robot: An Automatic Rapid Temperature Screening System

A Review on High‐Frequency Dielectric Elastomer Actuators: Materials, Dynamics, and Applications

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