Your search keyword '"Jung de Andrade M"' showing total 3 results

1. Sheath-run artificial muscles.

Author

Mu J, Jung de Andrade M, Fang S, Wang X, Gao E, Li N, Kim SH, Wang H, Hou C, Zhang Q, Zhu M, Qian D, Lu H, Kongahage D, Talebian S, Foroughi J, Spinks G, Kim H, Ware TH, Sim HJ, Lee DY, Jang Y, Kim SJ, and Baughman RH

Subjects

Nanotubes, Carbon, Tensile Strength, Artificial Organs, Carbon Fiber, Muscle Contraction, Muscle Fibers, Skeletal

Abstract

Although guest-filled carbon nanotube yarns provide record performance as torsional and tensile artificial muscles, they are expensive, and only part of the muscle effectively contributes to actuation. We describe a muscle type that provides higher performance, in which the guest that drives actuation is a sheath on a twisted or coiled core that can be an inexpensive yarn. This change from guest-filled to sheath-run artificial muscles increases the maximum work capacity by factors of 1.70 to 2.15 for tensile muscles driven electrothermally or by vapor absorption. A sheath-run electrochemical muscle generates 1.98 watts per gram of average contractile power-40 times that for human muscle and 9.0 times that of the highest power alternative electrochemical muscle. Theory predicts the observed performance advantages of sheath-run muscles., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2019

2. Artificial muscles from fishing line and sewing thread.

Author

Haines CS, Lima MD, Li N, Spinks GM, Foroughi J, Madden JD, Kim SH, Fang S, Jung de Andrade M, Göktepe F, Göktepe Ö, Mirvakili SM, Naficy S, Lepró X, Oh J, Kozlov ME, Kim SJ, Xu X, Swedlove BJ, Wallace GG, and Baughman RH

Subjects

Humans, Muscles chemistry, Muscles ultrastructure, Polymers, Porosity, Cotton Fiber, Nylons, Tensile Strength, Torsion, Mechanical

Abstract

The high cost of powerful, large-stroke, high-stress artificial muscles has combined with performance limitations such as low cycle life, hysteresis, and low efficiency to restrict applications. We demonstrated that inexpensive high-strength polymer fibers used for fishing line and sewing thread can be easily transformed by twist insertion to provide fast, scalable, nonhysteretic, long-life tensile and torsional muscles. Extreme twisting produces coiled muscles that can contract by 49%, lift loads over 100 times heavier than can human muscle of the same length and weight, and generate 5.3 kilowatts of mechanical work per kilogram of muscle weight, similar to that produced by a jet engine. Woven textiles that change porosity in response to temperature and actuating window shutters that could help conserve energy were also demonstrated. Large-stroke tensile actuation was theoretically and experimentally shown to result from torsional actuation.

Published

2014

3. Electrically, chemically, and photonically powered torsional and tensile actuation of hybrid carbon nanotube yarn muscles.

Author

Lima MD, Li N, Jung de Andrade M, Fang S, Oh J, Spinks GM, Kozlov ME, Haines CS, Suh D, Foroughi J, Kim SJ, Chen Y, Ware T, Shin MK, Machado LD, Fonseca AF, Madden JD, Voit WE, Galvão DS, and Baughman RH

Subjects

Absorption, Electricity, Hot Temperature, Hydrogen chemistry, Muscles ultrastructure, Optics and Photonics, Photons, Muscle Contraction, Muscles chemistry, Nanotubes, Carbon, Tensile Strength

Abstract

Artificial muscles are of practical interest, but few types have been commercially exploited. Typical problems include slow response, low strain and force generation, short cycle life, use of electrolytes, and low energy efficiency. We have designed guest-filled, twist-spun carbon nanotube yarns as electrolyte-free muscles that provide fast, high-force, large-stroke torsional and tensile actuation. More than a million torsional and tensile actuation cycles are demonstrated, wherein a muscle spins a rotor at an average 11,500 revolutions/minute or delivers 3% tensile contraction at 1200 cycles/minute. Electrical, chemical, or photonic excitation of hybrid yarns changes guest dimensions and generates torsional rotation and contraction of the yarn host. Demonstrations include torsional motors, contractile muscles, and sensors that capture the energy of the sensing process to mechanically actuate.

Published

2012