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Erschienen in:
The Design of E Glove Hand Function Evaluation Device Based on Fusion of Vision and Touch Kapitel lesen Erstes Kapitel lesen

2017 | OriginalPaper | Buchkapitel

Dynamic Analysis and Design of Lower Extremity Power-Assisted Exoskeleton

verfasst von : Shengli Song, Xinglong Zhang, Qing Li, Husheng Fang, Qing Ye, Zhitao Tan

Erschienen in: Wearable Sensors and Robots

Verlag: Springer Singapore

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Abstract

A new design of lower extremity power-assisted exoskeleton (LEPEX), is presented in this paper, which is used for transmitting the backpack weight of the wearer to the ground and enhancing human motion, with each joint driven by corresponding actuator. Primarily, a 7-bar human machine mathematical model is introduced and analyzed with different walking phases using Lagrange’s Equations. Second, dynamic parameters, such as torque and power consumptions of each joint in the sagittal plane are obtained for human with 75 kg payload in his (her) back with different conditions, i.e., flat walking and climbing stairs. Afterwards, the actuator for each joint is chosen based on the torque and power consumptions, i.e., a passive actuator for each knee joint and an active actuator for each ankle and hip joint; as well as the structure of LEPEX. Last but not least, the designed LEPEX is simulated under ADAMS environment by using wearer’s joint movement data, which is obtained from flat walking and climbing stairs experiments. Eventually, the simulation results are reported to witness the potentialities of the structure.

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Vorheriges Kapitel Study on a Novel Wearable Exoskeleton Hand Function Training System Based on EMG Triggering
Nächstes Kapitel Human Gait Trajectory Learning Using Online Gaussian Process for Assistive Lower Limb Exoskeleton
Literatur
Aaron MD, Hugh H (2008) Lower extremity exoskeleton and active orthoses: Challenges and state-of-the-art. IEEE T Robot 24(1):144–158CrossRef
Bogue Robert (2009) Exoskeletons and robotic prosthetics: a review of recent developments. Ind Robot Int J (S0143-991x) 36(5):421–427CrossRef
Yoshiyuki S. Centroid position detector device and wearing type action assistance device including centroid position detector device. USA, 20100271051A1. 28 Oct 2010
Channon M, Frankel VH (1979) The ball and socket ankle joint. J Bone Joint Surg 61B(1):85–89
Chu A, Kazerooni H, Zozz A (2005) On the biomimetic design of the Berkeley lower extremity exoskeleton (BLEEX). In: Proceeding of IEEE international conference robotics and automation. Barcelona, Spain, pp 4345–4352
DenBogert Van AJ (2003) Exotendons for assistance of human locomotion. Biomed Eng Online 2:17CrossRef
Fabio Z (2004) Theoretical and experimental issues in biped walking control based on passive dynamics. Doctoral dissertation, Sapienza University of Rome, Rome
Furusho J (1990) Sensor-based control of a nine-link biped. Int J Robot Res 9(2):83–98CrossRef
GB10000-88 (1988) human dimensions of Chinese adults
GB/T 17245-2004 (2004) Inertial parameters of adult human body
Grabowski AM, Herr H (2009) Leg exoskeleton reduces the metabolic cost of human hopping. J Appl Physiol 107(3):670–678CrossRef
Guizzo E, Goldstein H (2005) The Rise of the Body Bots: Exoskeletons are strutting out of the lab-and they are carring their creators with them. IEEE Spectr (S0018-9235) 42(10):50–56CrossRef
Hayashi T, Kawamoto H, Sankai Y (2005) Control method of robot suit HAL working as operator’s muscle using biological and dynamical information. 2005 IEEE/RSJ international conference on intelligent robots and systems. IEEE, USA, pp 3455–3460
Homayoon K (2008) Exoskeletons for human performance augmentation. Springer handbook of robotics. Springer, Germany, pp 773–793
Katubedda K, Kiguchi K et al (2009) Mechanical designs of active upper-limb exoskeleton robots state-of-the-art and design difficulties. In: Proceedings of IEEE 11th international conference on rehabilitation robotics. Kyoto International Conference Center, Japan, pp 178–187
Kawabata T, Satoh H, Sankai Y (2009) Working posture control of robot suit HAL for reducing structural stress. In: Proceeding of the 2009 IEEE international conference on robotics and biomimetics, pp 2013–2018
Kawamoto H, Sankai Y (2002a) Power assist system HAL-3 for gait disorder person. In: Proceeding of international conference computing helping people special needs (ICCHP) (Lecture Notes on Computer Science), vol 2398. Springer-Verlag, Berlin, Germany
Kawamoto H, Sankai Y (2002b) Power assist system HAL-3 for gait disorder person. In: Proceedings of the 8th international conference on computers helping people with special needs, pp 196–203
Kawamoto H, Lee S, Kanbe S, Sankai Y (2003) Power assist method for HAL-3 using EMG-based feedback controller. In: Proceeding of IEEE international conference system man cybernetics pp 1648–1653
Kazerooni H, Steger R (2006) The Berkeley lower extremity exoskeleton. Trans ASME J Dyn Syst Measure Control 128:14–25CrossRef
Kazerooni H, Racine J-L, Huang L, Steger R (2005) On the control of the Berkeley lower extremity exoskeleton (BLEEX). In: Proceedings of the 2005 IEEE international conference on robotics and automation. Barcelona, Spain, (4), pp 4353–4360
Lee S, Sankai Y (2002) Power assist control for walking aid with HAL-3 based on EMG and impedance adjustment around knee joint. In: IEEE/RSJ International conference intelligent robots and system. Lausanne , pp 1499–1504
Makinson BJ (1971) General Electric CO. Research and development prototype for machine augmentation of human strength and endurance, Hardiman I Project (General Electric Report S-71-1056). NY, Schenectady
Mu XP, Wu Q (2004) Development of a complete dynamic model of a planar five-link biped and sliding mode control of its locomotion during the double support phase. Int J Control 77(8):789–799MathSciNetCrossRefMATH
Ning LIU, Jun-feng LI, Qing-yi FENG, Tian-shu WANG (2007) Underwater human model simulation based on ADAMS. J Syst Simul 19(2):240–243
Qing Liang, Xian-xi Song, Feng Zhou (2010) Modeling and simulationg of biped robot based on ADAMS. Comput Simul 27(5):162–165
Riener R, Rabuffetti M, Frigo C (2002) Stair ascent and descent at different inclinations. Gait Posture 15:32–34CrossRef
Rose J, Gamble JG (1994) Human walking, 2nd edn. Williams and Wilkins, Baltimore, MD
Sakurai T, Sankai Y et al (2009) Development of motion instruction system with interactive robot suit HAL[C]. In: Proceedings of IEEE international conference on robotics and biomimetics. Robotics and Biomimetics (ROBIO), Japan, pp 1141–1147
Stansfield BW, Hillman SJ, Hazlewood ME, Lawson AM, Mann AM, Loudon IR, Robb JE (2001) Sagittal Joint Kinematics, moments, and powers are predominantly characterized by speed of progression. Not Age J Paed Orth 21:403–411
Stansfield BW, Hillman SJ, Hazlewood ME (2006) Regression analysis of gait parameters with speed in normal children walking at self-selected speeds. Gait Posture 23(3):288–294CrossRef
Sunghoom Kim, George Arwar and Kazeooni H. High-speed communication network for controls with the application on the exoskeleton. In: Proceeding of American control conference Boston Massachusetts 2004: 355–360
Valiente A (2005) Design of a quasi-passive parallel leg exoskeleton to augment load carrying for walking. Master’s thesis, Department of Mechanical Engineering Massachusetts Institute of Technology, Cambridge
Vaughan CL, Davis BL, O’Connor JC (1992) Dynamics of human Gait Kiboho, 2nd edn. Publishers Cape Town, Africa
Walsh CJ (2006) Biomimetic design of an underactuated leg exoskeleton for load-carrying augmentation. Master’s thesis, Department of Mechanical Engineering, Massachusetts Institute of Technology, Cambridge, 2006
Walsh CJ, Paluska D, Pasch K, Grand W, Valiente A, Herr H (2006) Development of a lightweight, underactuated exoskeleton for loadcarrying augmentation. In: Proceeding of IEEE international conference on robotics and automation. Orlando, FL, pp 3485–3491
Walsh CJ, Pasch K, Herr H (2006) An autonomous, underactuated exoskeleton for load-carrying augmentation. In: Proceeding IEEE/RSJ international conference on intelligence robots system (IROS). Beijing, China, pp 1410–1415
Wang Yi-ji, Li Jian-Jun (2011) A device that can raise and improve the function of walking: power of lower limb exoskeleton system design and application. J Rehabil Theory Pract China 17(7):628–631
Wang N, Wang J-H, Zhang M-W (2012) The gait of a human lower limb exoskeleton robot research status]. Chin J Orthop Clin Basic Res 4(1)
Xue Zhao-Jun, Jin Jing-na, Ming Dong et al (2008) The present state and progress of researches on gait recognition. J Biomed Eng 25(5):1217–1221
Yagn N (1890) Apparatus for facilitating walking, running, and jumping. US Patents 420 179 and 438 830
Yang Can-jun, Chen Ying, Lu Yu-xiang (2000) Intelligent man-machine integration system theory and its applied research. J Mech Eng 36(6):42–47CrossRef
Yoshiyuki S (2011) Wearing type behavior help device calibration device and control program. USA, 2011000432A1. 06 Jan 2011
Zoss A, Kazerooni H, Chu A (2005a) Berkeley Lower Extremity Exoskeleton (BLEEX). In: 2005 IEEE/RSJ International conference on intelligent robots and system (3), pp 3132–3139
Zoss A, Kazerooni H, Chu A (2005b) On the mechanical design of the Berkeley lower extremity exoskeleton (BLEEX). IEEE, pp 3764–3370
Zoss AB, Kazerooni H, Chu A (2006) Biomechanical design of the Berkeley lower extremity exoskeleton (BLEEX). IEEE/ASME Trans Mechatron 11(2):128–138CrossRef
Metadaten
Titel
Dynamic Analysis and Design of Lower Extremity Power-Assisted Exoskeleton
verfasst von
Shengli Song
Xinglong Zhang
Qing Li
Husheng Fang
Qing Ye
Zhitao Tan
Copyright-Jahr
2017
Verlag
Springer Singapore
Buch
Wearable Sensors and Robots

Print ISBN: 978-981-10-2403-0

Electronic ISBN: 978-981-10-2404-7

Copyright-Jahr: 2017

DOI
https://doi.org/10.1007/978-981-10-2404-7_13

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