Your search keyword '"Xulin Wei"' showing total 6 results

1. Thermally driven carbon nanotube@polycaprolactone coaxial artificial muscle fibers working in subzero environments

Author

Lizhong Dong, Xulin Wei, Ming Ren, and Jiangtao Di

Subjects

Artificial muscles, thermally driven, subzero environment, carbon nanotubes, polycaprolactone, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

ABSTRACTArtificial muscle fibers driven electrothermally with excellent properties of response, stroke, and work capacity are expected to serve in some intelligent structures and systems. However, muscle fibers that operate in subzero environments are highly needed in industrial production and aerospace applications but remain challenging. Herein, we reported a coaxial artificial muscle fiber by electrospinning a sheath of polycaprolactone (PCL) nanofibers on the surface of a carbon nanotube (CNT) fiber core, achieving the actuation in response to thermal at subzero temperatures. The CNT@PCL coaxial muscle fiber under 0.3 MPa achieved a maximum contractile stroke of ~18% as the temperature changed from −130°C to 45°C. The actuation mechanism at subzero temperatures of this muscle fiber was analyzed in combination with the temperature-deformation schematic curve of different polymers. Furthermore, a temperature sensor based on this muscle fiber was developed, due to the excellent linear relationship between the contraction and temperature. A 3D-printed prosthetic arm was designed to further exhibit the application demonstrations of this muscle fiber in subzero environments. This work provides new insights into artificial muscle fibers for serving in extreme environments with ultralow temperatures.

Published

2023

2. Stepwise Artificial Yarn Muscles with Energy-Free Catch States Driven by Aluminum-Ion Insertion

Author

Ming Ren, Panpan Xu, Yurong Zhou, Yulian Wang, Lizhong Dong, Tao Zhou, Jinke Chang, Jianfeng He, Xulin Wei, Yulong Wu, Xiaona Wang, Wei Chen, Jiangtao Di, and Qingwen Li

Subjects

Ions, Nanotubes, Carbon, General Engineering, General Physics and Astronomy, General Materials Science, Muscle, Skeletal, Aluminum, Muscle Contraction

Abstract

Present artificial muscles have been suffering from poor actuation step precision and the need of energy input to maintain actuated states due to weak interactions between guest and host materials or the unstable structural changes. Herein, these challenges are addressed by deploying a mechanism of reversible faradaic insertion and extraction reactions between tetrachloroaluminate ions and collapsed carbon nanotubes. This mechanism allows tetrachloroaluminate ions as a strong but dynamic "locker" to achieve an energy-free high-tension catch state and programmable stepwise actuation in the yarn muscle. When powered off, the muscle nearly 100% maintained any achieved contractile strokes even under loads up to 96,000 times the muscle weight. The actuation mechanism allowed the programmable control of stroke steps down to 1% during reversible actuation. The isometric stress generated by the yarn muscle (14.6 MPa in maximum, 40 times that of skeletal muscles) was also energy freely lockable and step controllable with high precision. Importantly, when fully charged, the muscle stored energy with a high capacity of 102 mAh g

Published

2022

3. High-Temperature-Tolerant Artificial Muscles Using Poly(p-phenylene benzobisoxazole) Composite Yarns

Author

Jianfeng He, Ming Ren, Lizhong Dong, Yulian Wang, Xulin Wei, Bo Cui, Yulong Wu, Yueran Zhao, Jiangtao Di, and Qingwen Li

Subjects

General Medicine

Published

2022

4. Artificial neuromuscular fibers by multilayered coaxial integration with dynamic adaption

Author

Lizhong Dong, Ming Ren, Yulian Wang, Guanghua Wang, Shiqin Zhang, Xulin Wei, Jianfeng He, Bo Cui, Yueran Zhao, Panpan Xu, Xiaona Wang, Jiangtao Di, and Qingwen Li

Subjects

Multidisciplinary

Abstract

Integrating sense in a thin artificial muscle fiber for environmental adaption and actuation path tracing, as a snail tentacle does, is highly needed but still challenging because of the interfacing mismatch between the fiber’s actuation and sensing components. Here, we report an artificial neuromuscular fiber by wrapping a carbon nanotube (CNT) fiber core in sequence with an elastomer layer, a nanofiber network, and an MXene/CNT thin sheath, achieving the ingenious sense-judge-act intelligent system in an elastic fiber. The CNT/elastomer components provide actuation, and the sheath enables touch/stretch perception and hysteresis-free cyclic actuation tracing due to its strain-dependent resistance. As a whole, the coaxial structure builds a dielectric capacitor that enables sensitive touchless perception. The key to seamless integration is to use a nanofiber interface that allows the sensing layer to adaptively trace but not restrict actuation. This work provides promising solutions for closed-loop control for future intelligent soft robots.

Published

2022

5. Self-sensing coaxial muscle fibers with bi-lengthwise actuation

Author

Ming Ren, Qingwen Li, Yulong Wu, Yulian Wang, Jianfeng He, Xulin Wei, Lizhong Dong, Jiangtao Di, and Jian Qiao

Subjects

Materials science, Muscle Fibers, Skeletal, 02 engineering and technology, Carbon nanotube, engineering.material, 010402 general chemistry, 01 natural sciences, law.invention, Coating, Biomimetics, law, General Materials Science, Electrical and Electronic Engineering, Composite material, Nanotubes, Carbon, Process Chemistry and Technology, Robotics, 021001 nanoscience & nanotechnology, Piezoresistive effect, 0104 chemical sciences, Mechanics of Materials, Bundle, engineering, Artificial muscle, Elongation, Coaxial, 0210 nano-technology, Actuator, Muscle Contraction

Abstract

Artificial muscle fibers as a promising biomimetic actuator are needed for such applications as smart soft robots, muscle function restoration, and physical augmentation. Currently developed artificial muscle fibers have shown attractive performance in contractile and torsional actuations. However, the contractile muscle fibers do not have the capability of stimulus-responsive elongation, and real-time identifying their contractile position by themselves is still challenging. We report herein the preparation of a Ti3C2Tx MXene/single walled carbon-nanotubes (SWCNTs)-coated carbon nanotube (CNT)@polydimethylsiloxane (PDMS) coaxial muscle fiber that integrates the important features of self-position sensing and bi-lengthwise actuation. The bi-lengthwise actuation is realized by utilizing the large expansion coefficient difference of PDMS in response to solvent and heat, which results in ∼5% maximum elongation by n-heptane adsorption and ∼19% maximum contraction by electric heating under the optimal conditions. Meanwhile, due to the piezoresistive effect of the MXene/SWCNTs layer, the resistance change of this coating layer is almost linearly dependent on the contraction of the coaxial muscle fiber, providing a function of real-time self-position sensing. Furthermore, an application of using a bundle of these multifunctional coaxial muscle fibers for a bionic arm has been demonstrated, which provides new insights into the design of integrated intelligent artificial muscles with synergistic multiple functions.

Published

2021

6. Artificial muscle fascicles integrated with high-performance actuation properties and energy-storage function

Author

Yulian Wang, Yueran Zhao, Ming Ren, Yurong Zhou, Lizhong Dong, Xulin Wei, Jianfeng He, Bo Cui, Xiaona Wang, Panpan Xu, Jiangtao Di, and Qingwen Li

Subjects

Renewable Energy, Sustainability and the Environment, General Materials Science, Electrical and Electronic Engineering

Published

2022