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Abstract

In the past decade, a rich repertoire of soft robots, designed from biomimetic and intuitive approaches, has been developed to overcome challenges faced by their rigid-bodied counterparts. However, these design approaches are greatly limited by the designers' experience and inspiration. In this article, the structural design problem is mathematically modeled under the framework of topology optimization, and solved by a new implementation tool that combines Abaqus/CAE and Matlab coding. Herein, a pneumatic soft gripper with two identical fingers was developed as a practical application. To fulfill the grasping task, each gripper finger is optimized to achieve its maximal bending deformation. The optimized gripper fingers are in high consistence with human fingers as indicated by pseudo-joints. Thereafter, the optimized gripper fingers are directly fabricated by three-dimensional printing technique with unprecedented fidelity regardless of high geometric complexity. Experimental results show that the gripper can grasp an elastic balloon, and each gripper finger is able to undergo a \documentclass{aastex}\usepackage{amsbsy}\usepackage{amsfonts}\usepackage{amssymb}\usepackage{bm}\usepackage{mathrsfs}\usepackage{pifont}\usepackage{stmaryrd}\usepackage{textcomp}\usepackage{portland, xspace}\usepackage{amsmath, amsxtra}\usepackage{upgreek}\pagestyle{empty}\DeclareMathSizes{10}{9}{7}{6}\begin{document} $${14.71^{\circ} }$$ \end{document} free travel bending and exert 0.23 N grasping force upon 0.06 MPa actuation pressure. The proposed approach is freely extendable to develop other types of soft robots and this represents an important step toward the goal of designing and fabricating soft robots automatically.

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References

Trivedi

, Rahn

, Kier

, et al. Soft robotics: biological inspiration, state of the art, and future research. Appl Bionics Biomech, 2008; 5:99–117.

Robinson

, Davies

JBC

. Continuum robots-a state of the art. In: Proceedings of 1999 IEEE International Conference on Robotics and Automation, Detroit, MI, May 10–15, 1999, pp. 2849–2854.

Rus

, Tolley

. Design, fabrication and control of soft robots. Nature, 2015; 521:467–475.

Laschi

, Mazzolai

, Cianchetti

. Soft robotics: technologies and systems pushing the boundaries of robot abilities. Sci Robot, 2016; 1:eaah3690.

Shepherd

, Ilievski

, Choi

, et al. Multigait soft robot. Proc Natl Acad Sci U S A, 2011; 108:20400–20403.

Tolley

, Shepherd

, Mosadegh

, et al. A resilient, untethered soft robot. Soft Robot, 2014; 1:213–223.

Seok

, Onal

, Wood

, et al. Peristaltic locomotion with antagonistic actuators in soft robotics. In: Proceedings of 2010 IEEE International Conference on Robotics and Automation, Anchorage, AK, May 03–08, 2010, pp. 1228–;1233.

Sugiyama

, Hirai

. Crawling and jumping by a deformable robot. Int J Rob Res, 2006; 25:603–620.

Lin

H-T

, Leisk

, Trimmer

. GoQBot: a caterpillar-inspired soft-bodied rolling robot. Bioinspir Biomim, 2011; 6:026007.

10.

Bartlett

, Tolley

, Overvelde

JTB

, et al. A 3D-printed functionally graded soft robot powered by combustion. Science, 2015; 349:161–165.

11.

Loepfe

, Schumacher

, Lustenberger

, et al. An untethered, jumping roly-poly soft robot driven by combustion. Soft Robot, 2015; 2:33–41.

12.

Godaba

, Li

, Wang

, et al. A soft jellyfish robot driven by a dielectric elastomer actuator. IEEE Robot Autom Lett, 2016; 1:624–631.

13.

Renda

, Giorgio-Serchi

, Boyer

, et al. Modelling cephalopod-inspired pulsed-jet locomotion for underwater soft robots. Bioinspir Biomim, 2015; 10:055005.

14.

Polygerinos

, Lyne

, Wang

, et al. Towards a soft pneumatic glove for hand rehabilitation. In: Proceeding of 2013 IEEE/RSJ International Conference on Intelligent Robots and Systems, Tokyo, Japan, November 03–07, 2013, pp. 1512–;1517.

15.

Maeder-York

, Clites

, Boggs

, et al. Biologically inspired soft robot for thumb rehabilitation. J Med Device, 2014; 8:020933.

16.

Agarwal

, Besuchet

, Audergon

, et al. Stretchable materials for robust soft actuators towards assistive wearable devices. Sci Rep, 2016; 6:34224.

17.

Mutlu

, Alici

, in het Panhuis

, Spinks

. 3D printed flexure hinges for soft monolithic prosthetic fingers. Soft Robot, 2016; 3:120–133.

18.

Kim

, Laschi

, Trimmer

. Soft robotics: a bioinspired evolution in robotics. Trends Biotechnol, 2013; 31:287–294.

19.

Wehner

, Truby

, Fitzgerald

, et al. An integrated design and fabrication strategy for entirely soft, autonomous robots. Nature, 2016; 536:451–455.

20.

Laschi

, Cianchetti

, Mazzolai

, et al. Soft robot arm inspired by the octopus. Adv Robot, 2012; 26:709–727.

21.

Grissom

, Chitrakaran

, Dienno

, et al. Design and experimental testing of the OctArm soft robot manipulator. In: Proceeding of Defense and Security Symposium on International Society for Optics and Photonics, Orlando, Florida, 2006, 62301F.

22.

Haghshenas-Jaryani

, Carrigan

, Wijesundara

MBJ

. Design and development of a novel soft-and-rigid hybrid actuator system for robotic applications. In: Proceeding of ASME 2015 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference, Boston, MA, August 02–05, 2015, V05AT08A047.

23.

Manti

, Hassan

, Passetti

, et al. A bioinspired soft robotic gripper for adaptable and effective grasping. Soft Robot, 2015; 2:107–116.

24.

Deimel

, Brock

. A novel type of compliant and underactuated robotic hand for dexterous grasping. Int J Rob Res, 2015; 35:161–185.

25.

Yap

, Ng

, Yeow

C-H

. High-force soft printable pneumatics for soft robotic applications. Soft Robot, 2016; 3:144–158.

26.

Daerden

, Lefeber

. Pneumatic artificial muscles: actuators for robotics and automation. Eur J Mech Environ Eng, 2002; 47:11–21.

27.

Mosadegh

, Polygerinos

, Keplinger

, et al. Pneumatic networks for soft robotics that actuate rapidly. Adv Funct Mater, 2014; 24:2163–2170.

28.

Connolly

, Polygerinos

, Walsh

, et al. Mechanical programming of soft actuators by varying fiber angle. Soft Robot, 2015; 2:26–32.

29.

Brown

, Rodenberg

, Amend

, et al. Universal robotic gripper based on the jamming of granular material. Proc Natl Acad Sci U S A, 2010; 107:18809–18814.

30.

Amend

, Brown

, Rodenberg

, et al. A positive pressure universal gripper based on the jamming of granular material. IEEE Trans Robot, 2012; 28:341–350.

31.

Wei

, Chen

, Ren

, et al. A novel, variable stiffness robotic gripper based on integrated soft actuating and particle jamming. Soft Robot, 2016; 3:134–143.

32.

Lipson

. Challenges and opportunities for design, simulation, and fabrication of soft robots. Soft Robot, 2014; 1:21–27.

33.

Ross

, Nemitz

, Stokes

. Controlling and simulating soft robotic systems: insights from a thermodynamic perspective. Soft Robot, 2016; 3:170–176.

34.

She

, Chen

, Shi

, et al. Modeling and validation of a novel bending actuator for soft robotics applications. Soft Robot, 2016; 3:71–81.

35.

Hiller

, Lipson

. Dynamic simulation of soft multimaterial 3d-printed objects. Soft Robot, 2014; 1:88–101.

36.

Moseley

, Florez

, Sonar

, et al. Modeling, design, and development of soft pneumatic actuators with finite element method. Adv Eng Mater, 2015; 18:978–988.

37.

Largilliere

, Coevoet

, Sanz-Lopez

, et al. Real-time control of soft-robots using asynchronous finite element modeling. In: Proceeding of 2015 IEEE International Conference on Robotics and Automation (ICRA), Seattle, WA, May 26–30, 2015, pp. 2550–2555.

38.

Hiller

, Lipson

. Automatic design and manufacture of soft robots. IEEE Trans Robot, 2012; 28:457–466.

39.

Bendsoe

, Sigmund

. Topology Optimization: Theory, Methods, and Applications. Berlin, Heidelberg: Springer Science & Business Media, 2013.

40.

Sigmund

, Maute

. Topology optimization approaches. Struct Multidiscipl Optim, 2013; 48:1031–1055.

41.

Sigmund

. On the design of compliant mechanisms using topology optimization. J Struct Mech, 1997; 25:493–524.

42.

Bendsøe

, Sigmund

. Material interpolation schemes in topology optimization. Arch Appl Mech, 1999; 69:635–654.

43.

Rojas-Labanda

, Stolpe

. Benchmarking optimization solvers for structural topology optimization. Struct Multidiscipl Optim, 2015; 52:527–547.

44.

Svanberg

. The method of moving asymptotes—a new method for structural optimization. Int J Numer Methods Eng, 1987; 24:359–373.

45.

Andreassen

, Clausen

, Schevenels

, et al. Efficient topology optimization in MATLAB using 88 lines of code. Struct Multidiscipl Optim, 2011; 43:1–16.

46.

Liu

, Tovar

. An efficient 3D topology optimization code written in Matlab. Struct Multidiscipl Optim, 2014; 50:1175–1196.

47.

Sigmund

. A 99 line topology optimization code written in Matlab. Struct Multidiscipl Optim, 2001; 21:120–127.

48.

Aage

, Andreassen

, Lazarov

. Topology optimization using PETSc: an easy-to-use, fully parallel, open source topology optimization framework. Struct Multidiscipl Optim, 2015; 51:565–572.

49.

, Dick

, Westermann

. A system for high-resolution topology optimization. IEEE Trans Vis Comput Graph, 2016; 22:1195–1208.

50.

Challis

, Roberts

, Grotowski

. High resolution topology optimization using graphics processing units (GPUs). Struct Multidiscipl Optim, 2014; 49:315–325.

51.

Hashin

, Shtrikman

. A variational approach to the theory of the elastic behaviour of multiphase materials. J Mech Phys Solids, 1963; 11:127–140.

52.

Zhang

, Wang

, et al. Design and analysis of soft grippers for hand rehabilitation. In: Proceeding of 12th International Manufacturing Science and Engineering Conference collocated with the JSME/ASME 2017 6th International Conference on Materials and Processing, Los Angeles, CA, June 2017, V004T05A003.

53.

Zhang

, Wang

, Fuh

JYH

, et al. Design and development of a soft gripper with topology optimization. In: Proceeding of 2017 IEEE/RSJ International Conference on Intelligent Robots and Systems, Vancouver, September 2017, pp. 6239–6244.

54.

Pedersen

CBW

, Buhl

, Sigmund

. Topology synthesis of large-displacement compliant mechanisms. Int J Numer Methods Eng, 2001; 50:2683–2705.

55.

Zhang

, Wang

, Li

, et al. A soft compressive sensor using dielectric elastomers. Smart Mater Struct, 2016; 25:035045.

56.

Zhang

, Wang

. Multi-axis soft sensors based on dielectric elastomer. Soft Robot, 2016; 3:3–12.

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Design and Development of a Topology-Optimized Three-Dimensional Printed Soft Gripper

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