Design and Analysis of Fiber-Reinforced Three-Cavity Structure of Soft Robot Hands

doi:10.12068/j.issn.1005-3026.2019.10.017

Abstract

Abstract: Based on the three-knuckle structure of a human hand， a fiber-reinforced three-cavity human-like soft body manipulator and a new type of pipe-laying method were proposed. The mathematical model of large deformation of the soft manipulator with a single finger was established by using Neo Hookean model. The deformation characteristics of the single-finger of the soft manipulator were analyzed， and the bending model and the torsion model were established. A 1∶1 mixture of Ecoflex 00-50 and Dragon skin 30 was used to make soft fingers， and the error correction of the theoretical model was carried out with the test data. The results showed that the theoretical model of the proposed new soft finger structure is consistent with the actual measurement data. Compared with the other structures， the new pipe-laying method increases the overall stability， and the conclusions can provide theoretical support for the development of human-like soft body manipulators.

Key words: soft robot, fiber-reinforced, three-cavity, finite element analysis, sensor

CLC Number:

TP242.6

FENG Nai-shi， WANG Hong， HU Fo， LI Kang. Design and Analysis of Fiber-Reinforced Three-Cavity Structure of Soft Robot Hands[J]. Journal of Northeastern University Natural Science, 2019, 40(10): 1461-1466.

References

[1]Fiorito G，Scotto P.Observational learning in octopus vulgaris［J］.Science，1992，256(5056):545-547.
[2]Kier W M，Smith K K.Tongues，tentacles and trunks:the biomechanics of movement in muscular hydrostats［J］.Zoological Journal of the Linnean Society，1985，83(4):307-324.
[3]肖宇.气动软体机械手设计及实验研究［D］.南京:东南大学，2016.(Xiao Yu.Design and experimental research of pneumatic soft robot hand［D］.Nanjing:Southeast University，2016.)
[4]Polygerinos P，Lyne S，Wang Z，et al.Towards a soft pneumatic glove for hand rehabilitation［C］//IEEE/RSJ International Conference on Intelligent Robots and Systems.Tokyo，2014:1512-1517.
[5]Tsuji T，Fukuda O，Shigeyoshi H，et al.Biomimetic impedance control of an EMG-controlled prosthetic hand［J］.Intelligent Robots & Systems，2000(1):377-382.
[6]Morrow J，Shin H S，Phillips-Grafflin C，et al.Improving soft pneumatic actuator fingers through integration of soft sensors，position and force control，and rigid fingernails［C］// IEEE International Conference on Robotics and Automation.Beijing，2016:5024-5031.
[7]Nagase J，Wakimoto S，Satoh T，et al.Design of a variable-stiffness robotic hand using pneumatic soft rubber actuators［J］.Smart Materials & Structures，2011，20(10):105015-105023.
[8]Yang Y，Chen Y，Li Y，et al.Bioinspired robotic fingers based on pneumatic actuator and 3D printing of smart material［J］.Soft Robotics，2017，4(2):147-162.
[9]张晞，王刚，何明，等.液压支架蕾形复合密封圈材料特性实验和有限元分析［J］.矿业科学学报，2016(1):64-72.(Zhang Xi，Wang Gang，He Ming，et al.Experimental and numerical study on bud shaped composite sealing ring of hydraulic support［J］.Journal of Mining Science and Technology，2016(1):64-72.)
[10]Gwinner J.Non-linear elastic deformations［J］.Acta Applicandae Mathematica，1988，11(2):191-193.
[11]Furer J，Castaeda P P.Macroscopic instabilities and domain formation in Neo-Hookean laminates［J］.Journal of the Mechanics & Physics of Solids，2018，118:98-114
[12]Homberg B S，Katzschmann R K，Dogar M R，et al.Haptic identification of objects using a modular soft robotic gripper［C］//IEEE/RSJ International Conference on Intelligent Robots and Systems.New York，2015:1698-1705.(上接第1460页)
[14]闫玉涛，李雪娟，胡广阳，等.石墨密封材料高温摩擦磨损行为及预测［J］.航空动力学报，2014，29(2):314-320.(Yan Yu-tao，Li Xue-juan，Hu Guang-yang，et al.Friction/wear behaviors and predication of graphite seal material under high temperature［J］.Journal of Aerospace Power，2014，29(2):314-320.)
[15]Soltani R，Heydarzadeh S M，Ansari M，et al.Effect of APS process parameters on high-temperature wear behavior of nickel-graphite abradable seal coatings［J］.Surface & Coatings Technology，2017，321:403-408.
[16]Rajaram G，Kumaran S，Rao T S，et al.Studies on high temperature wear and its mechanism of Al-Si/graphite composite under dry sliding conditions［J］.Tribology International，2010，43(11):2152-2158.
[17]布尚B.摩擦学导论［M］.葛世荣，译.北京:机械工业出版社，2007.(Bhushan Bharat.Introduction to tribology［M］.Translated by Ge Shi-rong.Beijing:China Machine Press，2007.)
[18]王伟，赵宗坚，张振生.单环圆周密封装置设计和应用研究［J］.航空发动机，2009，35(4):6-11.(Wang Wei，Zhao Zong-jian，Zhang Zhen-sheng.Design and application of single circumferential seal［J］.Aeroengine，2009，35(4):6-11.)

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