Multidirectional 3D-printed functionally graded modular joint actuated by TCPFL muscles for soft robots

Bhavar V, Kattire P, Thakare S, Singh R (2017) A review on functionally gradient materials (FGMs) and their applications. In: IOP conference series: materials science and engineering. IOP Publishing, Bristol

Erdogan F (1995) Fracture mechanics of functionally graded materials. Compos Eng 5(7):753–770

Knoppers G, Gunnink J, Van Den Hout J, Van Wliet W (2005) The reality of functionally graded material products. In: Intelligent production machines and systems-First I* PROMS virtual conference: proceedings and CD-ROM set, Elsevier, Amsterdam

Monzón M, Liu C, Ajami S, Oliveira M, Donate R, Ribeiro V, Reis RL (2018) Functionally graded additive manufacturing to achieve functionality specifications of osteochondral scaffolds. Bio-Des Manuf 1(1):69–75

Migliore SA, Brown EA, DeWeerth SP (2007) Novel nonlinear elastic actuators for passively controlling robotic joint compliance. J Mech Des 129(4):406–412

Zhang B, Luo Y, Ma L, Gao L, Li Y, Xue Q, Yang H, Cui Z (2018) 3D bioprinting: an emerging technology full of opportunities and challenges. Bio-Des Manuf 1(1):2–13

Ji K, Wang Y, Wei Q, Zhang K, Jiang A, Rao Y, Cai X (2018) Application of 3D printing technology in bone tissue engineering. Bio-Des Manuf 1(3):203–210

Richter C, Jentzsch S, Hostettler R, Garrido JA, Ros E, Knoll A, Rohrbein F, van der Smagt P, Conradt J (2016) Musculoskeletal robots: scalability in neural control. IEEE Robot Autom Mag 23(4):128–137

Mizuuchi I, Nakanishi Y, Sodeyama Y, Namiki Y, Nishino T, Muramatsu N, Urata J, Hongo K, Yoshikai T, Inaba M (2007) An advanced musculoskeletal humanoid kojiro. In: 2007 7th IEEE-RAS international conference on humanoid robots, IEEE

Kurumaya S, Suzumori K, Nabae H, Wakimoto S (2016) Musculoskeletal lower-limb robot driven by multifilament muscles. Robomech J 3(1):18

Niiyama R, Nagakubo A, Kuniyoshi Y (2007) Mowgli: a bipedal jumping and landing robot with an artificial musculoskeletal system. In: Proceedings 2007 IEEE international conference on robotics and automation, IEEE

Niiyama R, Kuniyoshi Y (2010) Design principle based on maximum output force profile for a musculoskeletal robot. Ind Robot Int J 37(3):250–255

Ikemoto S, Kimoto Y, Hosoda K (2015) Shoulder complex linkage mechanism for humanlike musculoskeletal robot arms. Bioinspiration Biomim 10(6):066009

Tadesse Y, Wu L, Saharan LK (2016) Musculoskeletal system for bio-inspired robotic systems. Mech Eng Mag Sel Artic 138(03):S11–S16

Wu L, Tadesse Y (2016) Musculoskeletal system for bio-inspired robotic systems based on ball and socket joints. In: ASME 2016 international mechanical engineering congress and exposition, American Society of Mechanical Engineers

Robertson MA, Paik J (2017) New soft robots really suck: vacuum-powered systems empower diverse capabilities. Sci Robot 2(ARTICLE):eaan6357

Must I, Sinibaldi E, Mazzolai B (2019) A variable-stiffness tendril-like soft robot based on reversible osmotic actuation. Nat Commun 10(1):344

Karnati N, Kent BA, Engeberg ED (2013) Bioinspired sinusoidal finger joint synergies for a dexterous robotic hand to screw and unscrew objects with different diameters. IEEE-ASME Trans Mechatron 18(2):612–623

Ransley M, Smitham P, Miodownik M (2017) Active chainmail fabrics for soft robotic applications. Smart Mater Struct 26(8):08LT02

Haines CS, Lima MD, Li N, Spinks GM, Foroughi J, Madden JD, Kim SH, Fang S, De Andrade MJ, Göktepe F (2014) Artificial muscles from fishing line and sewing thread. Science 343(6173):868–872

Almubarak Y, Tadesse Y (2017) Twisted and coiled polymer (TCP) muscles embedded in silicone elastomer for use in soft robot. Int J Intell Robot Appl 1(3):352–368

Wu L, Chauhan I, Tadesse Y (2018) A novel soft actuator for the musculoskeletal system. Adv Mater Technol 3(5):1700359

Tang XT, Li K, Liu YX, Zhou D, Zhao JG (2019) A soft crawling robot driven by single twisted and coiled actuator. Sens Actuators Phys 291:80–86

Tang X, Li K, Liu Y, Zhou D, Zhao J (2019) A general soft robot module driven by twisted and coiled actuators. Smart Mater Struct 28(3):035019. https://iopscience.iop.org/article/10.1088/1361-665X/aaff2f/meta

Yang Y, Li Y, Chen Y (2018) Principles and methods for stiffness modulation in soft robot design and development. Bio-Des Manuf 1(1):14–25

Bartlett NW, Tolley MT, Overvelde JTB, Weaver JC, Mosadegh B, Bertoldi K, Whitesides GM, Wood RJ (2015) A 3D-printed, functionally graded soft robot powered by combustion. Science 349(6244):161–165

Stratasys Ltd. 07/29/2019; Available from: https://www.stratasys.com/materials/

Mirzaali MJ, de la Nava AH, Gunashekar D, Nouri-Goushki M, Doubrovski E, Zadpoor AA (2019) Fracture behavior of bio-inspired functionally graded soft–hard composites made by multi-material 3D printing: the case of colinear cracks. Materials 12(17):2735

Salcedo E, Baek D, Berndt A, Ryu JE (2018) Simulation and validation of three dimension functionally graded materials by material jetting. Addit Manuf 22:351–359

Wu L, Karami F, Hamidi A, Tadesse Y (2018) Biorobotic systems design and development using TCP muscles. In: Electroactive polymer actuators and devices (EAPAD) XX. International Society for Optics and Photonics

LLC, m. Nichrome 70-30 Medium Temperature Resistor Material. [cited 2018; Available from: http://www.matweb.com/search/DataSheet.aspx?MatGUID=70c6833687d54cb4a000bd49ffd8e86c&ckck=1