doi:10.1007/s11465-023-0770-2

PDF(7129 KB)

Frontiers of Mechanical Engineering ›› 2023, Vol. 18 ›› Issue (4) : 54. DOI: 10.1007/s11465-023-0770-2

Mechanisms and Robotics - RESEARCH ARTICLE

作者信息 +

Design and experiment of a novel pneumatic soft arm based on a deployable origami exoskeleton

Yuwang LIU ¹^,² ,
Wenping SHI ¹^,²^,³ ,
Peng CHEN ¹^,²^,⁴ ,
Yi YU ¹^,²^,⁴ ,
Dongyang ZHANG ¹^,² ,
Dongqi WANG ¹^,²

Author information +

History +

Abstract

Soft arms have shown great application potential because of their flexibility and compliance in unstructured environments. However, soft arms made from soft materials exhibit limited cargo-loading capacity, which restricts their ability to manipulate objects. In this research, a novel soft arm was developed by coupling a rigid origami exoskeleton with soft airbags. The joint module of the soft arm was composed of a deployable origami exoskeleton and three soft airbags. The motion and load performance of the soft arm of the eight-joint module was tested. The developed soft arm withstood at least 5 kg of load during extension, contraction, and bending motions; exhibited bistable characteristics in both fully contracted and fully extended states; and achieved a bending angle of more than 240° and a contraction ratio of more than 300%. In addition, the high extension, contraction, bending, and torsional stiffnesses of the soft arm were experimentally demonstrated. A kinematic-based trajectory planning of the soft arm was performed to evaluate its error in repetitive motion. This work will provide new design ideas and methods for flexible manipulation applications of soft arms.

Keywords

pneumatic soft arm / soft airbag / deployable origami exoskeleton / bistable characteristics / cargo-loading capacity

引用本文

EndNote

Ris (Procite)

Bibtex

导出引用

. . Frontiers of Mechanical Engineering. 2023, 18(4): 54 https://doi.org/10.1007/s11465-023-0770-2

参考文献

原文顺序 | 文献年度倒序 | 文中引用次数倒序

[1]	Laschi C , Mazzolai B , Cianchetti M . Soft robotics: technologies and systems pushing the boundaries of robot abilities. Science Robotics, 2016, 1(1): eaah3690 CrossRef ADS Google scholar
[2]	Mazzolai B , Laschi C . A vision for future bioinspired and biohybrid robots. Science Robotics, 2020, 5(38): eaba6893 CrossRef ADS Google scholar
[3]	Renda F , Giorelli M , Calisti M , Cianchetti M , Laschi C . Dynamic model of a multibending soft robot arm driven by cables. IEEE Transactions on Robotics, 2014, 30(5): 1109–1122 CrossRef ADS Google scholar
[4]	Oliver-Butler K , Till J , Rucker C . Continuum robot stiffness under external loads and prescribed tendon displacements. IEEE Transactions on Robotics, 2019, 35(2): 403–419 CrossRef ADS Google scholar
[5]	Gong Z Y , Fang X , Chen X Y , Cheng J H , Xie Z X , Liu J Q , Chen B H , Yang H , Kong S H , Hao Y F , Wang T M , Yu J Z Wen L . A soft manipulator for efficient delicate grasping in shallow water: modeling, control, and real-world experiments. The International Journal of Robotics Research, 2021, 40(1): 449–469 CrossRef ADS Google scholar
[6]	Chen P , Yuan T W , Yu Y , Liu Y W . Design and modeling of a novel soft parallel robot driven by endoskeleton pneumatic artificial muscles. Frontiers of Mechanical Engineering, 2022, 17(2): 22 CrossRef ADS Google scholar
[7]	Olson G , Chow S , Nicolai A , Branyan C , Hollinger G , Mengüç Y . A generalizable equilibrium model for bending soft arms with longitudinal actuators. The International Journal of Robotics Research, 2021, 40(1): 148–177 CrossRef ADS Google scholar
[8]	Robertson M A , Paik J . New soft robots really suck: vacuum-powered systems empower diverse capabilities. Science Robotics, 2017, 2(9): eaan6357 CrossRef ADS Google scholar
[9]	Novelino L S , Ze Q J , Wu S , Paulino G H , Zhao R K . Untethered control of functional origami microrobots with distributed actuation. Proceedings of the National Academy of Sciences, 2020, 117(39): 24096–24101 CrossRef ADS Google scholar
[10]	Kim Y , Parada G A , Liu S D , Zhao X H . Ferromagnetic soft continuum robots. Science Robotics, 2019, 4(33): eaax7329 CrossRef ADS Google scholar
[11]	Margheri L , Laschi C , Mazzolai B . Soft robotic arm inspired by the octopus: I. From biological functions to artificial requirements. Bioinspiration & Biomimetics, 2012, 7(2): 025004 CrossRef ADS Google scholar
[12]	She Y , Chen J , Shi H L , Su H J . Modeling and validation of a novel bending actuator for soft robotics applications. Soft Robotics, 2016, 3(2): 71–81 CrossRef ADS Google scholar
[13]	Hawkes E W , Blumenschein L H , Greer J D , Okamura A M . A soft robot that navigates its environment through growth. Science Robotics, 2017, 2(8): eaan3028 CrossRef ADS Google scholar
[14]	Jiang H , Wang Z C , Jin Y S , Chen X T , Li P J , Gan Y H , Lin S , Chen X P . Hierarchical control of soft manipulators towards unstructured interactions. The International Journal of Robotics Research, 2021, 40(1): 411–434 CrossRef ADS Google scholar
[15]	Xu Y S , Qiu L , Yuan S F . Fabrication and actuation performance of selective laser melting additive-manufactured active shape-memory alloy honeycomb arrays. Actuators, 2022, 11(9): 242 CrossRef ADS Google scholar
[16]	Cheng N G , Gopinath A , Wang L F , Iagnemma K , Hosoi A E . Thermally tunable, self-healing composites for soft robotic applications. Macromolecular Materials and Engineering, 2014, 299(11): 1279–1284 CrossRef ADS Google scholar
[17]	Carlson J D , Jolly M R . MR fluid, foam and elastomer devices. Mechatronics, 2000, 10(4–5): 555–569 CrossRef ADS Google scholar
[18]	Li Y C , Li J C , Tian T F , Li W H . A highly adjustable magnetorheological elastomer base isolator for applications of real-time adaptive control. Smart Materials and Structures, 2013, 22(9): 095020 CrossRef ADS Google scholar
[19]	FirouzehASalernoMPaikJ. Soft pneumatic actuator with adjustable stiffness layers for multi-DOF actuation. In: Proceedings of 2015 IEEE/RSJ International Conference on Intelligent Robots and Systems. Hamburg: IEEE, 2015, 1117–1124
[20]	OgawaAObinataGHaseKDuttaANakagawaM. Design of lower limb prosthesis with contact pressure adjustment by MR fluid. In: Proceedings of the 30th Annual International Conference of the IEEE Engineering in Medicine and Biology Society. Vancouver: IEEE, 2008, 330–333
[21]	Gandhi F , Kang S G . Beams with controllable flexural stiffness. Smart Materials and Structures, 2007, 16(4): 1179 CrossRef ADS Google scholar
[22]	LindenrothLBackJSchoisengeierANohYWürdemannHAlthoeferKLiuH B. Stiffness-based modelling of a hydraulically-actuated soft robotics manipulator. In: Proceedings of 2016 IEEE/RSJ International Conference on Intelligent Robots and Systems. Daejeon: IEEE, 2016, 2458–2463
[23]	Gerboni G , Ranzani T , Diodato A , Ciuti G , Cianchetti M , Menciassi A . Modular soft mechatronic manipulator for minimally invasive surgery (MIS): overall architecture and development of a fully integrated soft module. Meccanica, 2015, 50(11): 2865–2878
[24]	Li Y T , Chen Y H , Yang Y , Wei Y . Passive particle jamming and its stiffening of soft robotic grippers. IEEE Transactions on Robotics, 2017, 33(2): 446–455 CrossRef ADS Google scholar
[25]	Zhu M Z , Mori Y , Wakayama T , Wada A , Kawamura S . A fully multi-material three-dimensional printed soft gripper with variable stiffness for robust grasping. Soft Robotics, 2019, 6(4): 507–519 CrossRef ADS Google scholar
[26]	Jiang Y K , Chen D S , Liu C , Li J . Chain-like granular jamming: a novel stiffness-programmable mechanism for soft robotics. Soft Robotics, 2019, 6(1): 118–132 CrossRef ADS Google scholar
[27]	Saito K , Pellegrino S , Nojima T . Manufacture of arbitrary cross-section composite honeycomb cores based on origami techniques. Journal of Mechanical Design, 2014, 136(5): 051011 CrossRef ADS Google scholar
[28]	Kim S J , Lee D Y , Jung G P , Cho K J . An origami-inspired, self-locking robotic arm that can be folded flat. Science Robotics, 2018, 3(16): eaar2915 CrossRef ADS Google scholar
[29]	WoodL JRendonJMalakR JHartlD. An origami-inspired, SMA actuated lifting structure. In: Proceedings of ASME 2016 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. Charlotte: ASME, 2016, V05BT07A024
[30]	KimJLeeD YKimS RChoK J. A self-deployable origami structure with locking mechanism induced by buckling effect. In: Proceedings of 2015 IEEE International Conference on Robotics and Automation. Seattle: IEEE, 2015, 3166–3171
[31]	Kaufmann J , Bhovad P , Li S Y . Harnessing the multistability of kresling origami for reconfigurable articulation in soft robotic arms. Soft Robotics, 2022, 9(2): 212–223 CrossRef ADS Google scholar
[32]	Lee J G , Rodrigue H . Armor-based stable force pneumatic artificial muscles for steady actuation properties. Soft Robotics, 2022, 9(3): 413–424 CrossRef ADS Google scholar
[33]	Lin Y Q , Yang G , Liang Y W , Zhang C , Wang W , Qian D H , Yang H Y , Zou J . Controllable stiffness origami “skeletons” for lightweight and multifunctional artificial muscles. Advanced Functional Materials, 2020, 30(31): 2000349 CrossRef ADS Google scholar
[34]	Kim W , Byun J , Kim J K , Choi W Y , Jakobsen K , Jakobsen J , Lee D Y , Cho K J . Bioinspired dual-morphing stretchable origami. Science Robotics, 2019, 4(36): eaay3493 CrossRef ADS Google scholar
[35]	Lee D Y , Kim J K , Sohn C Y , Heo J M , Cho K J . High-load capacity origami transformable wheel. Science Robotics, 2021, 6(53): eabe0201 CrossRef ADS Google scholar
[36]	Chen Y , Peng R , You Z . Origami of thick panels. Science, 2015, 349(6246): 396–400 CrossRef ADS Google scholar
[37]	HamzaMZekiosC LGeorgakopoulosS V. A thick origami four-patch array. In: Proceedings of 2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting. Atlanta: IEEE, 2019, 1141–1142

Nomenclature

F	Applied force
h	Half the height of the waterbomb origami structure
i	ith joint module
k_i	Curvature of the ith joint module
$K_{α}$ , $K_{β}$ , $K_{χ}$	Stiffnesses in the fully contracted, extended, and intermediate state, respectively
M	Torque
$O_{i}$	Position of the coordinate origin of the upper platform of the ith joint module
$^{i - 1} p_{i}$	Column vector of the ith joint module positions
r	Radius of the joint module
$_{i}^{i - 1} R$	Rotation matrix of the ith joint module
s_i	Arc length of the ith joint module
t	Thickness of the waterbomb origami structure
$_{i - 1}^{i} T$	Homogeneous matrix of the ith joint module
x_i, y_i, z_i	X, Y, and Z coordinate values of the end of the ith joint module, respectively
Y_i, Z_i	Y- and Z-axis of the coordinate system at the end of the ith joint module, respectively
$α$	Bending angle of soft arm
$β_{i}$	Rotation angle of the end of the ith joint module around $Z_{i}$
$μ$	Design angle of the origami pattern
$λ$	Folding angle of the waterbomb origami structure
$ϕ$	Displacement of soft arm
$φ_{i}$	Deflection angle of the ith joint module
$χ_{i}$	Rotation angle of the end of the ith joint module around Y_i
$δ_{i}$	Rotation angle of the end of the ith joint module around X_i

Acknowledgements

This work was supported by the National Natural Science Foundation of China (Grant Nos. 51975566, 61821005, and U1908214) and the Key Research Program of Frontier Sciences, CAS, China (Grant No. ZDBS-LY-JSC011).