2-UPS/RR Parallel Mechanism Used in Human Hip Joint Power Assist and Kinematic Performance
-
摘要: 为了帮助髋关节受损的患者完成行走运动,提出了一种适用于髋关节助力的2-UPS/RR并联机构. 该机构不仅可以满足髋关节助力所需要的前屈/后伸、内收/外展、内旋/外旋运动,还可以保证机构的旋转中心与不同患者的髋关节旋转中心重合. 计算了自由度,并应用解析法给出了机构的位置反解,建立了速度雅克比矩阵,通过对驱动参数的限定,求解了机构的工作空间. 最后,基于雅克比矩阵,对比分析了分别驱动移动副和虎克副2根旋转轴时机构的运动学性能. 结果表明:在规定的工作空间内驱动移动副时,机构具有良好的可操作性、运动灵活性和刚度特性. 相比当前的髋关节助力机构,其结构简单,有效避免了支链间不必要的干涉,减小了整个机构的占用体积. 设计的该机构适合髋关节助力训练.Abstract: To help patients with impaired hip joint walking exercise, a 2-UPS/RR parallel mechanism was presented, which is suitable for hip joint assisting. It meets the requirements of hip movement for flexion/extension adduction/abduction, pronation/supination, and its mechanism centres of rotations accurately match different patient’s hip. The mobility of the mechanism was calculated, inverse kinematics was solved by using the analytical method, and the velocity Jacobian matrix was established. By demarcating the driving parameters, the work space of the mechanism was coped with. Finally, in view of the Jacobian matrix, the kinematics performance of the mechanism was analyzed when driving mobile deputy and two axes of Hooke deputy, respectively. Results show that the mechanism is of favourable operability, flexibility and stiffness characteristics within the specified workspace. Compared wtih some existing hip joint power assist robots, the mechanism in simple structure can effectively avoid unnecessary interference between branches and significantly reduce the occupancy volume of the entire unit, absolutely with more advantages. Therefore, the designed mechanism is suitable for hip assist training.
-
Key words:
- hip joint assisting /
- parallel mechanism /
- operability /
- flexibility /
- stiffness characteristics
-
图 14 第2种驱动方式下机构的平均刚度
Figure 14. Mechanism’s average stiffness in the second drive mode
表 1 髋关节运动范围
Table 1. Movement range of hip joint(°)
运动方式 屈曲 外展 内旋 外旋 正常运动 37 7 5 9 极限运动 125 45 45 45 
下载: 导出CSV
表 2 机构的结构参数
Table 2. Architectural parameters of the mechanismm
参数 数值 d 0.15 L3 0.05 L2 0.20 A1 (0.13,-0.075,-0.2) A2 (-0.13,-0.075,-0.2) B1 (0.13,-0.08,-0.05) B2 (-0.13,-0.08,-0.05)
下载: 导出CSV
-
[1] LÜ G M, SUN L N, PENG L G.Rehabilitation robotics technology development status and key technology analysis[J]. Journal of Harbin Institute of Technology, 2004, 36(9): 1224-1227. (in Chinese) [2] ZHANG J J, HU X F, XU X L.Progress in lower limb rehabilitation robot[J]. Chinese Journal of Rehabilitation Theory and Practice, 2012, 18(8): 728-730. (in Chinese) [3] FANG T T, HAN J H, WANG H L, et al.New horizontal lower limb rehabilitation robot system design[J]. China Journal of Rehabilitation Medicine, 2013, 28(3): 246-250. (in Chinese) [4] ZHANG L X, LI C S, LIU F Q.Design and experimental analysis of multi-mode lower limb rehabilitation robot[J]. China Journal of Rehabilitation Medicine, 2011, 26(5): 464-466. (in Chinese) [5] 王兴松, 单晖, 徐继刚, 等. 一种基于套索传动的髋关节助力康复装置: 104825306 A [P].2015-08-12. [6] JEREMY O, MOHAMED B, AMALRIC O, et al.Development of an assistive motorized hip orthosis[C]//2013 IEEE International Conference on Rehabilitation Robotics. Washington: IEEE, 2013: 24-26 [7] PAN M, ZHANG D.Analysis of a novel design of a three-degree of freedom hip exoskeleton based on biomimetic parallel structure[C]//2011 First International Conference on Robot, Vision and Signal Processing. Oshawa: IEEE, 2011: 601-605. [8] SONG L P.Based on lower limb rehabilitation robotics 3-UPU parallel mechanism [D]. Chengdu: Xihua University, 2013. (in Chinese) [9] YU Y, TAO H B, LIANG W Y, et al.A parallel mechanism and pseudo-compliance control using on wearable power assist hips[C]//Proceedings of 2012 IEEE International Conference on Mechatronics and Automation. Chengdu: IEEE, 2012: 1502-1507. [10] YU Y, TAO H B, LIANG W Y, et al.A parallel mechanism used on human hip joint power assist[C]//Proceedings of 2009 IEEE International Conference on Robotics and Biomimetics. Guilin: IEEE, 2009: 1007-1012. [11] YU Y, LIANG W Y, GE Y J et al. Jacobian analysis for parallel mechanism using on human walking power assisting[C]//Proceedings of 2011 IEEE International Conference on Mechatronics and Automation. Beijing: IEEE, 2011: 282-288 [12] LIANG W Y.Wearable-type parallel robot research hip booster[D]. Hefei: University of Science and Technology of China, 2012. (in Chinese) [13] 顾冬云. 骨关节功能解剖学[M]. 6版. 北京: 人民军医出版社, 2011: 4-65. [14] 戴红. 人体运动学[M]. 北京: 人民卫生出版社, 2008: 17-50. [15] WANG M X, HUANG T.Kinematic analysis and scale synthesis of 3-SPR parallel mechanism[J]. Journal of Mechanical Engineering, 2013, 49(15): 22-27. (in Chinese) [16] CHEN X L, GAO Q, ZHAO Y S.Dexterity measures of 4-UPE-UPU parallel coordinate measuring machine[J]. Computer Integrated Manufacturing Systems, 2012, 18(6): 1200-1209. (in Chinese) [17] YOSHIKAWA T.Manipulability of robotic mechanism[J]. International Journal of Robotics Research, 1987, 4(2): 3-9. [18] SATISBRUG J K CRAIG J J. Articulated hands: force and kinematic issues[J]. International Journal of Robotics Research, 1982, l(1): 4-17. [19] LI Y, XU Q.Stiffness analysis for a 3-PUU parallel kinematic machine[J]. Mechanism and Machine Theory, 2008, 43(2): 186-200. -
下载:
点击查看大图
图(15) / 表(2)
计量
- 文章访问数: 119
- HTML全文浏览量: 65
- PDF下载量: 0
- 被引次数: 0
京公网安备 11010502036328号 京ICP备17033152号