4-4 Parallel Six-Axis Force Sensor Based on Performance Atlases 被引量：3

Force/Moment Isotropy of 8/4-4 Parallel Six-Axis Force Sensor Based on Performance Atlases

下载PDF

导出

摘要 A six-axis force sensor with parallel 8/4-4 structure is introduced and its measurement principle is analyzed.Based on condition numbers of Jacobian matrix spectral norm of the sensor,the relationship between the force and moment isotropy and some structural parameters is deduced.Orthogonal test methods are used to determine the degree of primary and secondary factors that have significant effect on sensor characteristics.Furthermore,the relationship between each performance index and the structural parameters of the sensor is analyzed by the method of the atlas,which lays a foundation for structural optimization design of the force sensor. A six-axis force sensor with parallel 8/4-4 structure is introduced and its measurement principle is analyzed.Based on condition numbers of Jacobian matrix spectral norm of the sensor,the relationship between the force and moment isotropy and some structural parameters is deduced.Orthogonal test methods are used to determine the degree of primary and secondary factors that have significant effect on sensor characteristics.Furthermore,the relationship between each performance index and the structural parameters of the sensor is analyzed by the method of the atlas,which lays a foundation for structural optimization design of the force sensor.

作者 Song Weishan Li Chenggang Wang Chunming Song Yong Wu Zefeng Rajnathsing Hemant

机构地区 College of Mechanical and Electrical Engineering

出处《Transactions of Nanjing University of Aeronautics and Astronautics》 EI CSCD 2018年第6期1018-1026,共9页 南京航空航天大学学报（英文版）

基金 supported by the Open Foundation of Graduate Innovation Base(Laboratory)of Nanjing University of Aeronautics and Astronautics (No.kfjj20170512) the National Natural Science Foundation of China(No. 51175263)

关键词 six-axis FORCE sensor JACOBIAN matrix condition number ISOTROPY ORTHOGONAL test indices ATLASES six-axis force sensor Jacobian matrix condition number isotropy orthogonal test indices atlases

分类号 TN925 [电子电信—通信与信息系统]

引文网络
相关文献

参考文献3

1贾振元,褚宏飞,刘巍,林盛,卢晓红.基于Stewart结构六维大力传感器的性能分析及结构优化[J].仪器仪表学报,2010,31(2):341-346. 被引量：13
2姚裕,吴洪涛.3-DOF转动柔索驱动风洞机构的力雅可比矩阵[J].南京航空航天大学学报,2011,43(1):75-78. 被引量：8
3佟志忠,姜洪洲,何景峰,黄其涛.复合单叶双曲面上广义Gough-Stewart并联机构加速度传感器各向同性优化设计[J].机械工程学报,2014,50(13):35-41. 被引量：5

二级参考文献37

1熊有伦.机器人力传感器的各向同性[J].自动化学报,1996,22(1):10-18. 被引量：35
2GAILLETA, REBOULET C. An isostatic six component force and torque sensor[C]. Proceedings of the 13th Intemational Symposium on Industrial Robotics, 1983: 102-111.
3UCHIYAMA M, HAKOMORI K A. A few considerations on structure design of force sensor [C]. Proceedings of the Third Annual Conference on Japan Robotics Society, 1985:17-18.
4DWARAKANATH T A, DASGUPTA B. Design and development of a Stewart platform-based force-torque sensor[J]. Mechatronics, 2001,11(7):793-809.
5SVININ M M, UCHIYAMA M. Optimal geometric structures of force/torque sensors[J]. Intemational Journal of Robotics Research, 1995,14(6):560-573.
6PRZEMIENIECKI J S. Method of matrix structural analysis[J]. New York: McGraw-Hill, 1968.
7CHUL-GOO K. Closed-form force sensing of a 6-axisforce transducer based on the stewart platform[J]. Sensors and Actuators A 90,2001:31-37.
8KOSUGE K, OKUDA M, KAWAMATA H, et al. In- put/output force analysis of parallel link manipulators[J]. IEEE J. Robotics Automat, 1993:714-719.
9YANG C H .The space model and dimensional types of the four-bar mechanisms[J]. Mechanism and Machine Theory, 1987,22(1):71-76.
10Albus J,Bostelman R,Dagalakis N.The nist robockane[J].Journal of Robotic Systems,1993,10(5):709-724.

共引文献23

1李玉民.机械手柔性抓取切换控制系统设计与仿真分析[J].国外电子测量技术,2010,29(10):30-33. 被引量：5
2房庆华,张军,李映君,贾振元,钱敏.轴用压电式六维大力值测力仪分载研究[J].仪器仪表学报,2011,32(2):439-444. 被引量：2
3王志军,侯雨雷,姚建涛,叶冬,赵永生.双层预紧式6维力传感器预紧力对精度影响分析[J].机器人,2012,34(4):393-398. 被引量：1
4刘志华,唐晓强,邵珠峰,王立平.6自由度索并联机构的振动特性[J].机械工程学报,2013,49(3):49-55. 被引量：14
5陈子明,陈谊超,杨凤霞,黄真.两种三自由度并联角台机构的转动空间分析[J].机械工程学报,2014,50(5):48-56. 被引量：6
6李敏,刘俊,秦岚,刘京诚.平板式压电六维力传感器静态性能研究[J].机械工程学报,2014,50(6):1-7. 被引量：10
7于春战,刘晋浩,孙治博.一种并联式六维加速度传感器参数优化研究[J].仪器仪表学报,2014,35(10):2216-2222. 被引量：5
8于春战,刘晋浩,孙治博.基于Kane方法的并联式六维加速度传感器动态特性研究[J].仪器仪表学报,2015,36(7):1611-1617. 被引量：9
9周中喜,张志安,盛娟红.基于DSP的柔索驱动并联机构控制系统[J].兵工自动化,2016,35(6):60-65. 被引量：1
10李昂,韩康,霍琦,于慧莉.基于OpenMP的Stewart并联机器人控制系统[J].传感器与微系统,2016,35(7):67-69. 被引量：1

同被引文献8

1李东洁,邱江艳,尤波,王焕灵.机械臂三维避障算法研究[J].控制工程,2010,17(5):669-673. 被引量：7
2徐丰羽,Yang Zhong,Jiang Guoping.An analyzing and experimental method based on the resultant motion signals for SCARA manipulator joints[J].High Technology Letters,2017,23(3):279-285. 被引量：4
3邓伟,张其万,刘平,宋锐.基于双种群遗传混沌优化算法的最优时间轨迹规划[J].计算机集成制造系统,2018,24(1):101-106. 被引量：29
4李黎,尚俊云,冯艳丽,淮亚文.关节型工业机器人轨迹规划研究综述[J].计算机工程与应用,2018,54(5):36-50. 被引量：115
5唐新星,王平,范大川.工业机器人运动学与轨迹规划仿真[J].重型机械,2018(2):61-65. 被引量：5
6连黎明.基于时间最优的机器人关节轨迹规划方法[J].组合机床与自动化加工技术,2018(9):57-60. 被引量：12
7侯庆隆,杨冬,郭士杰.工业机器人能耗优化方法研究综述[J].计算机工程与应用,2018,54(22):1-9. 被引量：13
8Wang Zhijun,He Jing,Cui Bingyan,Li Zhanxian.Dynamic analysis of double-layer and pre-stressed multi-limb six-axis force sensor[J].High Technology Letters,2019,25(2):189-196. 被引量：1

引证文献3

1涂云婷,金敏慧,张成功,李以贵.用于流速测量的微型力传感器的研制[J].微纳电子技术,2019,56(12):992-998. 被引量：1
2李国洪,王远亮.基于B样条和改进遗传算法的机器人时间最优轨迹规划[J].计算机应用与软件,2020,37(11):215-223. 被引量：27
3Wang Zhijun,Liu Lu,Cui Bingyan,He Jing,Li Zhanxian.Optimal design and experiment research of an orthogonal-parallel six-axis force/torque sensor[J].High Technology Letters,2021,27(2):184-192.

二级引证文献28

1古劲,吴泰羽,李传军,张宾,张亚伟.基于改进三次B样条的灌木修剪运动轨迹光顺算法研究[J].农业机械学报,2021,52(S01):89-97. 被引量：6
2贺诗涛,申立勇.一类参数曲线的积累平均弧长参数化方法[J].吉林大学学报（理学版）,2021,59(2):286-294. 被引量：3
3张国印,孟想,李思照.基于果蝇优化算法的无人机航路规划方法[J].无线电通信技术,2021,47(3):344-352. 被引量：9
4韩涛,李静,黄友锐,徐善永,许家昌.煤矿救援机器人机械臂轨迹规划算法研究[J].工矿自动化,2021,47(11):45-52. 被引量：11
5戴祯,刘卫东,徐景明,李乐.基于高阶多项式的爬游机器人足端轨迹规划[J].计算机测量与控制,2021,29(11):159-164. 被引量：5
6杨成超.基于Matlab的UR5机器人相贯焊接模型运动学分析和轨迹规划[J].机械传动,2021,45(12):68-73. 被引量：10
7韩斌,高公如,丁荣诚,林海波.基于轨迹规划的挖掘机遥控系统研究与开发[J].现代制造技术与装备,2022,58(1):1-8. 被引量：2
8樊依圣,徐鸣,刘文威,董成举.基于半实物仿真的工业机器人末端振动分析[J].自动化与信息工程,2022,43(1):25-32. 被引量：2
9胡俊辉,孙博,孟婥,张豪,孙以泽.基于时间-冲击的喷胶机器人轨迹优化算法[J].东华大学学报（自然科学版）,2022,48(1):72-78. 被引量：4
10张华文,刘子亮.基于时间最优的工业机器人关节空间轨迹规划[J].工业仪表与自动化装置,2022(2):46-50. 被引量：2

1Chuan He, Weijun Zhu, Guang Qin Gu, Tao Jiang, Liang Xu, Bao Dong Chen, Chang Bao Han, Dichen Li, Zhong Lin Wang.Integrative square-grid triboelectric nanogenerator as a vibrational energy harvester and impulsive force sensor[J].Nano Research,2018,11(2):1157-1164. 被引量：9
2Li-Min Jin,Na-Xiu Wang,Wan-Qian Zhu,Feng-Gang Bian,Zhong-Min Xu.FEA-based structural optimization design of a side cooling collimating mirror at SSRF[J].Nuclear Science and Techniques,2017,28(11):198-203.
3Lingling YANG,Hanyu LI.Condition Numbers for Indefinite Least Squares Problem with Multiple Right-Hand Sides[J].Journal of Mathematical Research with Applications,2017,37(6):725-742.
4Fan Huiyang,Gan Ning,Tao Qiong,Bao Xuhui,Liu Yanping.Synthesis and Catalytic Performance of Environmental Friendly Co(Salen) Complex[J].Meteorological and Environmental Research,2016,7(4):64-66.
5Lian-Dong Lin,Cheng-Jun Qiu,Xiang Yu,Peng Zhou.Equal Radial Force Structure Pressure Sensor Data Analysis and Finite Element Analysis[J].国际计算机前沿大会会议论文集,2015(1):90-92.
6杨正武.力密度在悬索结构找形中的应用[J].四川建材,2019,45(1):94-95.
7Yu Zheng,San Li,Chuanshan Zou,Xiaojian Ma,Guocai Zhang.Analysis of PM2.5 concentrations in Heilongjiang Province associated with forest cover and other factors[J].Journal of Forestry Research,2019,30(1):269-276. 被引量：6
8Rui Wang,Qingke Zhu,Hao Ma.Changes in freezing and thawing indices over the source region of the Yellow River from 1980 to 2014[J].Journal of Forestry Research,2019,30(1):257-268. 被引量：6
9Fei-fei Liu,Yan-ming Song,Hai-long Yu,Wen-ding Lin,Jie Zhang,Zhi-hui Si,Ming-kang Ding,Xiao-ting Rui.Study on the influence of projectile on muzzle disturbance[J].Defence Technology（防务技术）,2018,14(5):570-577. 被引量：3
10Ntombifuthi Mthabela,Vusi Ndlovu.The Relationship between Corporate Real Estate and Economic Cycle[J].Journal of Modern Accounting and Auditing,2018,14(10):538-560.

Transactions of Nanjing University of Aeronautics and Astronautics

2018年第6期

浏览历史

内容加载中请稍等...