Sage Journals: Discover world-class research

Abstract

Traditional actuators, such as motors as well as hydraulic or pneumatic artificial muscles, demonstrate excessive noise, a heavy weight, and a large size, which limit their practical application in many areas. Therefore, for many decades, scientists have worked to develop new types of silent, small, and light actuators. In this article, a novel soft actuator (actuator₃) with a high load-to-weight ratio from silicone and a low-boiling liquid (ethanol: actuator_3E or water: actuator_3W) is presented and is compared with two actuators (actuator₁ and actuator₂) fabricated according to a method described in the literature. Compared with actuator₁ and actuator₂, actuator₃ shows a larger volume expansion, output force, and load-to-weight ratio when heated. Owing to the weaker stability and repeatability of actuator_3E, many different kinds of applications based on actuator_3W are proposed, such as robotic hands and underwater rolling robots with color variations. The experimental results demonstrate that the method proposed in this article may be a viable alternative for fabricating low-cost soft actuators with high load-to-weight ratios that can be useful for future applications of soft robots.

Get full access to this article

View all access options for this article.

References

Hollingum

. Robots in agriculture. Ind Robot, 1999; 26:438–445.

Avgousti

, Christoforou

, Panayides

, et al. Medical telerobotic systems: current status and future trends. BioMed Eng Online, 2016; 15:96.

Chung

, Rhee

, Shim

, et al. Door-opening control of a service robot using the multifingered robot hand. IEEE Trans Indus Electr,, 2009; 56:3975–3984.

Honarpardaz

, Tarkian

, Ölvander

, et al. Finger design automation for industrial robot grippers: a review. Robot Auton Syst, 2017; 87:104–119.

Jacobsen

, Iversen

, Knutti

, Johnson

, Biggers

. Design of the Utah/MIT dextrous hand. In: Proceedings 1986 IEEE International Conference on Robotics and Automation, Vol. 3, New York, NY, 1986, pp. 1520–1532.

Zhu

, Mori

, Wakayama

, et al. A fully multi-material three-dimensional printed soft gripper with variable stiffness for robust grasping. Soft Robot, 2019:6:507–519.

Al-Rubaiai

, Pinto

, Qian

, et al. Soft actuators with stiffness and shape modulation using 3D-printed conductive polylactic acid material. Soft Robot, 2019; 6:318–332.

Fei

, Wang

, Pang

. A novel fabric-based versatile and stiffness-tunable soft gripper integrating soft pneumatic fingers and wrist. Soft Robot, 2019; 6:1–20.

Zhang

, Zhang

, Hingorani

, et al. Fast-response, stiffness-tunable soft actuator by hybrid multimaterial 3D printing. Adv Funct Mater, 2019; 29:1806698.

10.

Yamaguchi

, Takemura

, Yokota

, et al. A robot hand using electro- conjugate fluid: Grasping experiment with balloon actuators inducing a palm motion of robot hand. Sensors Actuat A Phys, 2012; 174:181–188.

11.

Martinez

, Glavan

, Keplinger

, et al. Soft actuators and robots that are resistant to mechanical damage. Adv Funct Mater, 2014:24:3303–3310.

12.

, Chang

, Li

. Soft robot with a novel variable friction design actuated by SMA and electromagnet. Smart Mater Struct, 2018; 27:115020 (11pp).

13.

W-B

, Zhang

W-M

, Zou

H-X

, Peng

Z-K

, Meng

. A fast rolling soft robot driven by dielectric elastomer. IEEE/ASME Trans Mech, 2018; 23:1630–1640.

14.

Jain

, Datta

, Majumder

. Design and control of an IPMC artificial muscle finger for micro gripper using EMG signal. Mechatronics, 2013:23:381–394.

15.

Altmüller

, Schwödiauer

, Kaltseis

, et al. Large area expansion of a soft dielectric membrane triggered by a liquid gaseous phase change. Appl Phys A, 2011; 105:1–3.

16.

Nakahara

, Narumi

, Niiyama

, et al. Electric phase-change actuator with inkjet printed flexible circuit for printable and integrated robot prototyping. 2017 IEEE International Conference on Robotics and Automation (ICRA) Singapore, 2017, pp. 1856–1863.

17.

Garrad

, Soter

, Conn

, et al. Driving soft robots with low-boiling point fluids. 2019 2nd IEEE International Conference on Soft Robotics (RoboSoft) COEX, Seoul, Korea 2019, pp. 74–79.

18.

, Guo

, Anderson

, et al. Bio-inspired polymer composite actuator and generator driven by water gradients. Science, 2013; 339:186–189.

19.

Zhou

, Li

, Chen

, et al. A large-deformation phase transition electrothermal actuator based on carbon nanotube-elastomer composites. J Mater Chem B, 2016; 4:1228–1234.

20.

Miriyev

, Stack

, Lipson

. Soft material for soft actuators. Nat Commun, 2017; 8:596.

21.

Wang

, Yao

, Wang

, et al. Large-magnitude transformable liquid-metal composites. ACS Omega, 2019; 4:2311–2319.

22.

Acome

, Mitchell

, Morrissey

, et al. Hydraulically amplified self-healing electrostatic actuators with muscle-like performance. Science, 2018; 359:61–65.

23.

Haines

, Spinks

, John

, et al. Artificial muscles from fishing line and sewing thread. Science, 2014; 343:868–872.

24.

Lee

, Li

, Haines

, et al. Electrochemically powered, energy-conserving carbon nanotube artificial muscles. Adv Mater, 2017; 29:1700870.

25.

Katzschmann

, DelPreto

, MacCurdy

, et al. Exploration of underwater life with an acoustically controlled soft robotic fish. Sci Robot, 2018; 3:eaar3449.

26.

Marchese

, Onal

, Rus

. Autonomous Soft robotic fish capable of escape maneuvers using fluidic elastomer actuators. Soft Robot, 2014; 1:75–87.

27.

Urai

, Sawada

, Hiasa

, et al. Design and control of a ray-mimicking soft robot based on morphological features for adaptive deformation. Artif Life Robotics, 2015; 20:237–243.

28.

Kim

, Kim

, Jung

, et al. A biomimetic undulatory tadpole robot using ionic polymer–metal composite actuators. Smart Mater Struct, 2005; 14:1579–1585.

29.

, Shang

, Chen

, et al. Bioinspired living structural color hydrogels. Sci Robot, 2018; 3:eaar8580.

30.

Roach

, Yuan

, Kuang

, et al. Long liquid crystal elastomer fibers with large reversible actuation strains for smart textiles and artificial muscles. ACS Appl Mater Interfaces, 2019; 11:19514–19521.

31.

. Position control based on the estimated bending force in a soft robot with tunable stiffness. Mech Syst Signal Process, 2019; 134:106335.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

11.22 MB

14.48 MB

0.00 MB

Design and Fabrication of a Low-Cost Silicone and Water-Based Soft Actuator with a High Load-to-Weight Ratio

Abstract

Get full access to this article

References

Supplementary Material