气动人工肌肉在康复器械中的应用现状

doi:10.3969/j.issn.1006-9771.2020.04.014

《中国康复理论与实践》 ›› 2020, Vol. 26 ›› Issue (4): 463-466.doi: 10.3969/j.issn.1006-9771.2020.04.014

气动人工肌肉在康复器械中的应用现状

周彬滨,邹任玲()

上海理工大学医疗器械与食品学院,上海市 200093

收稿日期:2019-05-06 修回日期:2019-06-04 出版日期:2020-04-25 发布日期:2020-04-27
通讯作者: 邹任玲 E-mail:zourenling@163.com
作者简介:周彬滨(1995-),男,汉族,湖南邵阳市人,硕士研究生,主要研究方向：精密医疗器械。
基金资助:
上海市科学技术委员会科研计划项目(19441904500)

Application of Pneumatic Artificial Muscle in Rehabilitation Equipment (review)

ZHOU Bin-bin,ZOU Ren-ling()

School of Medical Instrument and Food Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China

Received:2019-05-06 Revised:2019-06-04 Published:2020-04-25 Online:2020-04-27
Contact: ZOU Ren-ling E-mail:zourenling@163.com
Supported by:
Shanghai Science and Technology Committee Research Plan(19441904500)

摘要/Abstract

摘要：

本文介绍国内外气动人工肌肉在康复医疗器械中的应用现状,重点分析近年来气动人工肌肉在上肢和下肢康复器械中的应用,其中上肢康复器械包括手部、手腕和手臂,下肢康复器械包括腿部、膝关节和踝关节;应用实例介绍了气动人工肌肉的工作特点和应用范围,并且对同功能康复器械对比分析。

关键词: 气动人工肌肉, 上肢康复, 下肢康复, 康复机器人, 综述

Abstract:

This paper introduced the application of pneumatic artificial muscles in rehabilitation medical equipment at home and abroad, and emphatically analyzed the application of pneumatic artificial muscle in upper limb rehabilitation instruments and lower limb rehabilitation instruments in recent years, among which upper limb rehabilitation instruments included hand, wrist and arm, and lower limb rehabilitation instruments included leg, knee and ankle. The working characteristics and application scope of the application examples were introduced, and a comparative analysis of the same functional rehabilitation equipment was made.

Key words: pneumatic artificial muscle, upper limb rehabilitation, lower limb rehabilitation, rehabilitant robot, review

中图分类号:

R496

周彬滨,邹任玲. 气动人工肌肉在康复器械中的应用现状[J]. 《中国康复理论与实践》, 2020, 26(4): 463-466.

ZHOU Bin-bin,ZOU Ren-ling. Application of Pneumatic Artificial Muscle in Rehabilitation Equipment (review)[J]. 《Chinese Journal of Rehabilitation Theory and Practice》, 2020, 26(4): 463-466.

参考文献 36

[1]	沈卫红, 沈英, 李丽. 康复器械对脑卒中患者偏瘫肢体功能恢复的作用研究[J]. 中国医疗器械信息, 2018, 24(4):47-48.
[2]	董珊. 康复器械对脑卒中患者偏瘫肢体功能恢复的作用研究[J]. 中国医疗器械信息, 2018, 24(23):123-124.
[3]	Klute G K, Czerniecki J M, Hannaford B. McKibben artificial muscles: pneumatic actuators with biomechanical intelligence[C]. IEEE/ASME International Conference on Advanced Intelligent Mechatronics, IEEE, 1999: 221-226.
[4]	卫玉芬, 李小宁. 气动人工肌肉的进展和应用[J]. 机床与液压, 2003(1):37-38.
[5]	张远深, 刘明春, 赵娜, 等. McKibben气动人工肌肉技术的发展历程[J]. 液压与气动, 2008(7):13-15.
[6]	Kandel M, Beis J M, Le Chapelain L, et al. Non-invasive cerebral stimulation for the upper limb rehabilitation after stroke: a review[J]. Ann Phys Rehabil Med, 2012, 55(9-10):657-680. doi: 10.1016/j.rehab.2012.09.001 pmid: 23084320
[7]	陈学斌, 高海鹏, 刘文勇, 等. 手外骨骼康复技术研究进展[J]. 中国医疗设备, 2016, 31(2):86-91.
[8]	胡鑫, 张颖, 李继才, 等. 一种外骨骼式手功能康复训练器的研究[J]. 生物医学工程学杂志, 2016, 33(1):23-30.
[9]	Bao G, Li K, Xu S, et al. Motion identification based on sEMG for flexible pneumatic hand rehabilitator[J]. Ind Robot, 2015, 42(1):25-35. doi: 10.1108/IR-08-2014-0376
[10]	Shiota K, Tarvainen T V J, Sekine M, et al. Development of a robotic thumb rehabilitation system using a soft pneumatic actuator and a pneumatic artificial muscles-based parallel link mechanism[C]. International Conference on Intelligent Autonomous Systems, Springer, Cham, 2016: 525-537.
[11]	Tjahyono A P, Aw K C, Devaraj H, et al. A five-fingered hand exoskeleton driven by pneumatic artificial muscles with novel polypyrrole sensors[J]. Ind Robot, 2013, 40(3):251-260. doi: 10.1108/01439911311309951
[12]	Al-Fahaam H, Davis S, Nefti-Meziani S. The design and mathematical modelling of novel extensor bending pneumatic artificial muscles (EBPAMs) for soft exoskeletons[J]. Robot Auton Syst, 2018, 99:63-74. doi: 10.1016/j.robot.2017.10.010
[13]	Meng W, Sheng B, Klinger M, et al. Design and control of a robotic wrist orthosis for joint rehabilitation[C]. IEEE International Conference on Advanced Intelligent Mechatronics, IEEE, 2015: 1235-1240.
[14]	黄明, 黄心汉, 袁勇, 等. 2自由度腕关节康复机器人的代理滑模控制方法[J]. 华中科技大学学报(自然科学版), 2015, 43(S1):298-301.
[15]	Andrikopoulos G, Nikolakopoulos G, Manesis S. Design and development of an exoskeletal wrist prototype via pneumatic artificial muscles[J]. Meccanica, 2015, 50(11):2709-2730. doi: 10.1007/s11012-015-0199-8
[16]	Al-Fahaam H, Davis S, Nefti-Meziani S. Wrist rehabilitation exoskeleton robot based on pneumatic soft actuators[C]. International Conference for Students on Applied Engineering, IEEE, 2016: 491-496.
[17]	姚建涛, 李海利, 曹开彬, 等. 柔性可穿戴腕部动力手套的设计与分析[J]. 机械工程学报, 2018, 54(19):1-9.
[18]	Das S, Kishishita Y, Tsuji T, et al. ForceHand Glove: a wearable force-feedback glove with pneumatic artificial muscles (PAMs)[J]. IEEE Robot Autom Lett, 2018, 3(3):2416-2423.
[19]	Tu X, Han H, Huang J, et al. Upper limb rehabilitation robot powered by PAMs cooperates with FES arrays to realize reach-to-grasp trainings[J]. J Healthc Eng, 2017, 2017:1282934.
[20]	付亏杰, 孙丽楠, 刘云芳, 等. 虚拟现实技术在康复治疗中的应用[J]. 承德医学院学报, 2018, 35(5):425-429.
[21]	郭萌, 涂细凯, 何际平, 等. 基于模糊PI控制的穿戴式上肢康复机器人[J]. 华中科技大学学报(自然科学版), 2015, 43(S1):355-358.
[22]	花国辉. 下肢康复机器人训练改善缺血性脑卒中偏瘫患者下肢功能的临床效果研究[J]. 中国医疗器械信息, 2019, 25(7):88-89.
[23]	滕燕, 杨罡, 李小宁, 等. 下肢康复机器人技术及气动肌肉的应用[J]. 机床与液压, 2012, 40(15):137-140.
[24]	Wan S, Yang M, Xi R, et al. Design and control strategy of humanoid lower limb exoskeleton driven by pneumatic artificial muscles[C]. 2016 23rd International Conference on Mechatronics and Machine Vision in Practice, IEEE, 2016: 1-5.
[25]	Sun Y P, Chen S C, Liang Y C, et al. Design of a bionic-inspired exoskeleton robot for lower limb assist[J]. J Vibroengineering, 2016, 18(8):5452-5461. doi: 10.21595/jve.2016.17427
[26]	Su C, Chai A, Tu X, et al. Passive and active control strategies of a leg rehabilitation exoskeleton powered by pneumatic artificial muscles[J]. Int J Pattern Recognit Artif Intell, 2017, 31(10):1759021. doi: 10.1142/S0218001417590212
[27]	Park Y L, Santos J, Galloway K G, et al. A soft wearable robotic device for active knee motions using flat pneumatic artificial muscles[C]. IEEE International Conference on Robotics and Automation, IEEE, 2014: 4805-4810.
[28]	Dao Q T, Yamamoto S. Assist-as-needed control of a robotic orthosis actuated by pneumatic artificial muscle for gait rehabilitation[J]. Appl Sci, 2018, 8(4):499-514. doi: 10.3390/app8040499
[29]	Diteesawat R S, Helps T, Taghavi M, et al. High strength bubble artificial muscles for walking assistance[C]. IEEE International Conference on Soft Robotics, IEEE, 2018: 388-393.
[30]	刘海涛, 熊坤, 贾昕胤, 等. 3自由度冗余驱动下肢康复并联机构的运动学优化设计[J]. 天津大学学报(自然科学与工程技术版), 2018, 51(4):357-366.
[31]	Noda T, Takai A, Teramae T, et al. Robotizing double-bar ankle-foot orthosis[C]. IEEE International Conference on Robotics and Automation, IEEE, 2018: 2782-2787.
[32]	Ulkir O, Akgun G, Kaplanoglu E. Mechanical design and analysis of a pneumatic ankle foot orthosis[C]. Electric Electronics, Computer Science, Biomedical Engineerings' Meeting, IEEE, 2018: 1-4.
[33]	Hong J C, Suzuki S, Fukushima Y, et al. Development of high-dorsiflexion assistive robotic technology for gait rehabilitation[C]. IEEE International Conference on Systems, Man, and Cybernetics, IEEE, 2018: 3801-3806.
[34]	Park Y L, Chen B, Pérez-Arancibia N O, et al. Design and control of a bio-inspired soft wearable robotic device for ankle-foot rehabilitation[J]. Bioinspir Biomim, 2014, 9(1):1-17.
[35]	Kim H, Park H, Lee W, et al. Design of wearable orthopedic devices for treating forward head postures using pneumatic artificial muscles and flex sensors[C]. 2017 14th International Conference on Ubiquitous Robots and Ambient Intelligence, IEEE, 2017: 809-814.
[36]	Zi B, Yin G, Zhang D. Design and optimization of a hybrid-driven waist rehabilitation robot[J]. Sensors, 2016, 16(12):2-15. doi: 10.3390/s16010002

气动人工肌肉在康复器械中的应用现状

Application of Pneumatic Artificial Muscle in Rehabilitation Equipment (review)

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