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Abstract
An underactuated finger structure actuated by tendon-driven system is presented. Kinematics and static analysis of the finger is done, and the results indicate that the prosthetic finger structure is effective and feasible. Based on the design of finger, a prosthetic hand is designed. The hand is composed of 5 independent fingers and it looks more like humanoid. Its size is about 85% of an adult’s hand and weights about 350 g. Except the thumb finger, each finger is actuated by one DC motor, gear head and a tendon, and has three curling/extension joints. The thumb finger which is different from other existing prostheses is a novel design scheme. The thumb finger has four joints including three curling/extension joints and a joint which is used to realize the motion of the thumb related to the palm, and these joints are also driven by one DC motor, harmonic drive and a tendon. The underactuation and adaptive curling/extension motion of the finger are realized by joint torsion springs. A high-powered chip of digital signal processing (DSP) is the main part of the electrical system which is used for the motors control, data collection, communication with external controlling source, and so on. To improve the reliability of the hand, structures and sensors are designed and made as simply as possible. The hand has strong manipulation capabilities that have been verified by finger motion and grasping tests and it can satisfy the daily operational needs and psychological needs of deformities.
Keywords
prosthetic hand
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tendon-driven mechanism
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underactuation
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kinematics and static analysis
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Yi-wei Liu, Fei Feng, Yi-fu Gao.
HIT prosthetic hand based on tendon-driven mechanism.
Journal of Central South University, 2014, 21(5): 1778-1791 DOI:10.1007/s11771-014-2124-z
| [1] |
ChappellP H, KyberdP J. Prehensile control of a hand prosthesis by a microcontroller [J]. Biomedical Engineering, 1991, 13(5): 363-369
|
| [2] |
Otto bock system electro-hands [R/OL]. [2010-01-25]. http://www.Ottobock.com.
|
| [3] |
KyberdP J, LightC M, CappellP H, NightingaleJ M, WhatleyD, EvansM. The design of anthropomorphic prosthetic hands: A study of the Southampton hand [J]. Robotica, 2001, 19(6): 593-600
|
| [4] |
DechevN, LeghornW L, NeumannS. Multiple finger passive adaptive grasp prosthetic hand [J]. Mechanism and Machine Theory, 2001, 36: 1157-1173
|
| [5] |
YangJ Z, EstebanP P, KarimA M, AmosP, LindkvistL. A multifingered hand prosthesis [J]. Mechanism and Machine Theory, 2004, 39: 555-581
|
| [6] |
ZolloL, RoccellaS, GuglielmelliE, CarrozzaM C, DarioP. Biomechatronic design and control of an anthropomorphic artificial hand of prosthetics hand robotic applications [J]. IEEE/ ASME Transactions on Mechatronics, 2007, 12(4): 418-429
|
| [7] |
CiprianiC, ControzziM, CarrozzaM C. Progress towards the development of the smarth and transtadial prosthesis [C]. 2009 IEEE 11th International Conference on Rehabilitation Robotics, 2009, Piscataway, USA, IEEE Press: 682-687
|
| [8] |
ConnollyC. Prosthetic hands from touch bionicsm [J]. Industrial Robot, 2008, 35(4): 290-293
|
| [9] |
WangX-q, LiuY-w, LiuHong. Design and control of a coupling mechanism-based prosthetic hand [J]. Journal of Shanghai Jiaotong University (Science), 2010, 15(5): 571-577
|
| [10] |
YangD-p, ZhaoJ-d, LiuY-w, LiuHong. An anthropomorphic robot hand developed based on underactuated mechanism and controlled by EMG signals [J]. Journal of Bionic Engineer, 2009, 6(3): 255-263
|
| [11] |
BiagiottiL, LottiF, MelchiorriC, VassuraG. Mechatronics design of innovative fingers for anthropomorphic robot hands [C]. Proceedings of the 2003 IEEE International Conference on Robotics & Automation. Taipei, 20032122-2127
|
| [12] |
ThierryL, LionelB, ClementM. Underacutation in robotic grasping hands [J]. Machine Intelligence & Robotic Control, 2002, 4(3): 1-11
|
| [13] |
BirglenL, GosselinM. On the force capability of underactuated fingers [C]. Proceedings of the 2003 IEEE Conference on Robotics and Automation, 2003, Taipei, IEEE Press: 1139-1145
|
| [14] |
YangQ-h, ZhangL-i, RuanJ, XuF, BaoG-j, ShenJ-bing. Investigation into the motion law of human finger joint during grasping [J]. China Mechanical Engineering, 2004, 15(13): 1154-1156
|
| [15] |
XiongY-lunFundamentals of robot techniques [M], 1996, Wuhan, Huazhong University of Science and Technology Press: 35-50
|
| [16] |
PalliG, MelchiorriC. Model and control of tendon-sheath transmission systems [C]. Proceedings of the 2006 IEEE International Conference on Robotics and Automation, 2006, Orlando, Florida, USA, IEEE Press: 988-993
|
| [17] |
ZhangT, JiangL, LiuHong. A novel grasping force control strategy for multi-fingered prosthetic hand [J]. Journal of Central South University, 2012, 19(6): 1537-1542
|
