Clawed Miniature Inchworm Robot Driven by Electromagnetic Oscillatory Actuator 被引量：7

Clawed Miniature Inchworm Robot Driven by Electromagnetic Oscillatory Actuator

导出

摘要 In this research we propose a novel inchworm robot, which is composed of an Electromagnetic Oscillatory Actuator （EOA） and claws. The EOA consists of a yoke, a magnet, and a coil. The overall robot size is 12.2 mm x 11 mm x 9 mm （length x height ~ width）. The locomotion of the robot is achieved by different amounts of slips when the robot stretches and contracts its front leg. To realize locomotion, the working conditions were calculated theoretically and the calculated input signal was applied to the robot. The performance of the inchworm robot was evaluated experimentally with varying input voltages and frequencies. A simple op-amps based driving circuit was used to provide a square-wave input. Travel speed, average distance per step of the robot, and moving distance of the leg and body at each step were measured. The maximum travel speed was 36 mm-s-1 at 30 Hz, which validates our simple locomotion strategy experimentally. In this research we propose a novel inchworm robot, which is composed of an Electromagnetic Oscillatory Actuator （EOA） and claws. The EOA consists of a yoke, a magnet, and a coil. The overall robot size is 12.2 mm x 11 mm x 9 mm （length x height ~ width）. The locomotion of the robot is achieved by different amounts of slips when the robot stretches and contracts its front leg. To realize locomotion, the working conditions were calculated theoretically and the calculated input signal was applied to the robot. The performance of the inchworm robot was evaluated experimentally with varying input voltages and frequencies. A simple op-amps based driving circuit was used to provide a square-wave input. Travel speed, average distance per step of the robot, and moving distance of the leg and body at each step were measured. The maximum travel speed was 36 mm-s-1 at 30 Hz, which validates our simple locomotion strategy experimentally.

作者 Kyung-min Lee Youngshik Kim Jamie K. Paik Buhyun Shin

机构地区 Korean Intellectual Property Office Department of Mechanical Engineering The Institute of Mechanical Engineering

出处《Journal of Bionic Engineering》 SCIE EI CSCD 2015年第4期519-526,共8页 仿生工程学报（英文版）

关键词 electromagnetic actuator micro mobile robot INCHWORM CRAWLER locomotion electromagnetic actuator, micro mobile robot, inchworm, crawler, locomotion

分类号 TN322.8 [电子电信—物理电子学] TQ113.76 [化学工程—无机化工]

引文网络
相关文献

参考文献1

1Quoc-Viet Nguyen Hoon Cheol Park.Design and Demonstration of a Locust-Like Jumping Mechanism for Small-Scale Robots[J].Journal of Bionic Engineering,2012,9(3):271-281. 被引量：21

二级参考文献31

1Nguyen Q V, Park H C, Goo N S, Byun D Y. Characteristics of a beetle's free flight and a flapping-wing system that mimics beetle flight. Journal of Bionic Engineering, 2010, 7, 77-86.
2Wood R J. The first takeoff of a biologically inspired at-scale robotic insect. )EEE Transactions on Robotics, 2008, 24, 341-347.
3Ozcan O, Wang H, Taylor J D, Sitti M. Surface tension driven water strider robot using circular footpads. Proceed- ings of 1EEE International Conference on Robotics and Automation, Anchorage, AK, USA, 2010, 3799-3804.
4Zhang W, Guo S, Asaka K. Development of underwater microrobot with biomimetic locomotion. Journal of Applied Bionics and Biomechanics, 2006, 3,245-252.
5Birch M C, Quinn R D, Hahm G, Phillips S M, Drennan B T,Fife A J, Beer R D, Yu X, Garverick S L, Laksanacharoen S, Pollack A J, Ritzmann R E. Cricket-based robots: Introduc- ing an autonomous hybrid microrobot propelled by legs and supported by legs and wheels. IEEE Robotics & Automation Magazine, 2002, 9, 20-30.
6Quinn R D, Nelson G M, Bachmann R J, Kingsley D A, Offi J, Ritzmann R E. Insect designs for improved robot mobility. Proceedings of 4th International Conference on Climbing and Walking Robots, Karlsruhe, Germany, 2001, 69-76.
7Ward C C, Iagnemma K. A dynamic-model-based wheel slip detector for mobile robots on outdoor terrain. IEEE Trans- actions on Robotics, 2008, 24, 821-831.
8Hirose S, Yamada H. Snake-like robots: Machine design of biologically inspired robots. IEEE Magazine, 2009, 16, 88-98.
9Heitler W J. The locust jump: Specialisations of the metathoracic femoral-tibial joint. Journal of Comparative Physiology, 1974, 89, 93-104.
10Bennet-Clark H C. The energetics of the jump of the locust Schistocerca gregaria. Journal of Experimental Biology, 1975, 63, 53-83.

共引文献20

1Longbao Han,Zhouyi Wang,Aihong Ji,Zhendong Dai.The Mechanics and Trajectory Control in Locust Jumping[J].Journal of Bionic Engineering,2013,10(2):194-200. 被引量：8
2Jie Chen Yubin Liu Jie Zhao He Zhang Hongzhe Jin.Biomimetic Design and Optimal Swing of a Hexapod Robot Leg[J].Journal of Bionic Engineering,2014,11(1):26-35. 被引量：8
3Diansheng Chen Junmao Yin Kewei Chen Kai Zhao Benguang Zhang.Prototype Design and Experimental Study on Locust Air-Posture Righting[J].Journal of Bionic Engineering,2014,11(3):459-468. 被引量：7
4陈科位,陈殿生,张自强,沈奇,凌潇.仿蝗虫跳跃机器人弹跳腿分析与设计[J].中国科技论文,2015,10(10):1127-1130. 被引量：1
5王国彪,陈殿生,陈科位,张自强.仿生机器人研究现状与发展趋势[J].机械工程学报,2015,51(13):27-44. 被引量：184
6陈殿生,张自强,陈科位.仿生蝗虫机构着陆缓冲过程中的能量分配[J].机械工程学报,2015,51(13):196-202. 被引量：9
7杨茜,宋光明,陈天元,张军,宋爱国.一种弹跳机器人姿态调节中离散和连续运动建模与实验研究[J].机器人,2016,38(2):160-168. 被引量：2
8Dian-Sheng Chen,Zi-Qiang Zhang,Ke-Wei Chen.Dynamic model and performance analysis of landing buffer for bionic locust mechanism[J].Acta Mechanica Sinica,2016,32(3):551-565. 被引量：5
9Ziqiang Zhang,Diansheng Chen,Kewei Chen,Hanlong Chen.Analysis and Comparison of Two Jumping Leg Models for Bioinspired Locust Robot[J].Journal of Bionic Engineering,2016,13(4):558-571. 被引量：5
10王寰,吉爱红,戴振东,李力,贺伟,沈欢.一种仿蝗虫跳跃机器人的能量转换机制及跳跃稳定性设计[J].中国机械工程,2018,29(4):379-384. 被引量：4

同被引文献43

1李斌,何斌,苏永清.湿吸型仿生六足机器人的设计[J].华中科技大学学报（自然科学版）,2008,36(S1):210-212. 被引量：4
2周群,何斌,岳继光.蚂蚁的吸附力来源及其分泌液作用[J].力学学报,2007,39(3):428-432. 被引量：12
3DAI ZhenDong,GORB Stanislav.Contact mechanics of pad of grasshopper (Insecta:ORTHOPTERA) by finite element methods[J].Chinese Science Bulletin,2009,54(4):549-555. 被引量：9
4江励,管贻生,蔡传武,朱海飞,周雪峰,张宪民.仿生攀爬机器人的步态分析[J].机械工程学报,2010,46(15):17-22. 被引量：40
5阎世梁,张华,王银玲,肖晓萍.极坐标下基于迭代学习的移动机器人轨迹跟踪控制[J].计算机应用,2010,30(8):2017-2020. 被引量：11
6黎明和,何斌,岳继光,陆汉雄,周艳敏.湿吸附机理及其在仿生爬壁机器人中的应用[J].机器人,2010,32(5):577-585. 被引量：10
7江航,杨晓非,江汉红.船用吸附蠕动攀爬式机器人的设计与实现[J].舰船科学技术,2010,32(9):31-34. 被引量：2
8何斌,周艳敏,黎明和,秦海燕.湿吸仿生爬壁机器人分层控制系统[J].同济大学学报（自然科学版）,2010,38(12):1813-1817. 被引量：2
9黎明和,何斌,秦海燕,周艳敏,陆汉雄,岳继光.具有黏附方向性及自适应性的仿生湿吸足垫研究[J].科学通报,2011,56(7):529-535. 被引量：4
10WANG LiXin ZHOU Qiang XU ShuYan.Role of locust Locusta migratoria manilensis claws and pads in attaching to substrates[J].Chinese Science Bulletin,2011,56(8):789-795. 被引量：14

引证文献7

1Chang-Woo Song,Dong-Jun Lee,Seung-Yop Lee.Bioinspired Segment Robot with Earthworm-like Plane Locomotion[J].Journal of Bionic Engineering,2016,13(2):292-302. 被引量：5
2Buhyun Shin,Youngshik Kim,Jamie Paik,Kyung-min Lee.Miniaturized Twin-legged Robot with an Electromagnetic Oscillatory Actuator[J].Journal of Bionic Engineering,2018,15(1):106-113. 被引量：2
3Xinyi Liu,Zhiwei Liu,Yangsheng Zhu,Jiaming Leng,Mingjing Qi,Jianmei Huang,Xiaojun Yan.Moving Mechanism of a High-speed Insect-scale Microrobot via Electro-magnetically Induced Vibration[J].Journal of Bionic Engineering,2021,18(3):662-673. 被引量：1
4LIU Dasheng,YAN Guozheng.Biomechanical Analysis of a Radial Expansion Mechanism of Intestinal Robot Coupling with Hyperelastic Intestinal Wall[J].Journal of Shanghai Jiaotong university(Science),2022,27(4):552-560.
5眭翔,徐林森,周瑞吉,刘进福,龙杰.仿尺蠖多模式爬壁机器人设计与控制方法研究[J].计算机测量与控制,2022,30(10):155-161. 被引量：1
6眭翔,周瑞吉,徐林森,刘进福,龙杰,李泽林.基于Hopf振荡器的船舱检测机器人步态规划研究[J].机床与液压,2022,50(24):37-44. 被引量：3
7裴香丽,刘书豪,师瑞卓,魏安民,吴志伟,戴振东.仿生爬壁机器人:研究基础、关键技术及发展预测[J].科学通报,2024,69(17):2380-2400.

二级引证文献12

1Buhyun Shin,Youngshik Kim,Jamie Paik,Kyung-min Lee.Miniaturized Twin-legged Robot with an Electromagnetic Oscillatory Actuator[J].Journal of Bionic Engineering,2018,15(1):106-113. 被引量：2
2张东光,左国标,佟金,张智泓.蚯蚓仿生注液沃土装置设计与试验[J].农业工程学报,2019,35(19):29-36. 被引量：3
3何子瀚,方虹斌,徐鉴.仿蚯蚓移动机器人离散步态控制与相位差控制特性比较[J].机器人,2020,42(6):697-708. 被引量：6
4Xinyi Liu,Zhiwei Liu,Yangsheng Zhu,Jiaming Leng,Mingjing Qi,Jianmei Huang,Xiaojun Yan.Moving Mechanism of a High-speed Insect-scale Microrobot via Electro-magnetically Induced Vibration[J].Journal of Bionic Engineering,2021,18(3):662-673. 被引量：1
5魏国莲,李积元.四自由度串联机器人用电磁作动器设计[J].传感器与微系统,2022,41(4):81-85.
6眭翔,周瑞吉,徐林森,刘进福,龙杰,李泽林.基于Hopf振荡器的船舱检测机器人步态规划研究[J].机床与液压,2022,50(24):37-44. 被引量：3
7郭惠,耿宝光.基于机器学习算法的人体步态异常状态检测与识别方法[J].智能计算机与应用,2023,13(10):25-28. 被引量：1
8Bingzhu Wang,Xiangrui Ye.Finite Element Simulation Analysis of a Novel 3D-FRSPA for Crawling Locomotion[J].Computer Modeling in Engineering & Sciences,2024,139(5):1401-1425.
9曾潇丰,尹灿辉,刘青,吴宇列,肖定邦.昆虫级微型爬行机器人的研究综述[J].南京航空航天大学学报,2024,56(3):387-406.
10Yu Liu,Qingbiao Shi,Zhen Chen.Design and Gait Planning of a Worm-inspired Metameric Robot for Pipe Crawling[J].Journal of Bionic Engineering,2024,21(3):1265-1277.

1张伟,汪岳峰,董伟.用光电倍增管测量微光像增强器噪声[J].应用光学,2002,23(3):26-27. 被引量：2
2张伟,汪岳峰,董伟.用光电倍增管测量微光像增强器噪声[J].光电子技术,2001,21(4):281-283.
3谢忠锋,李党会.彩色显像管[J].显示器件技术,2002(3):50-50.
4龚国友.一种新型激光扫描偏转器的设计研究[J].现代电子技术,2011,34(18):139-141. 被引量：1
5QIU Shuye and B. M. Gibbs (Physics Department, Shantou Uaiversity. Shantou 515063)Acoustics Research Unit, Livcrpool University, P. O. Box. 147, L69 3BX, U.K..The design and dynamic performance of a moment actuator[J].Chinese Journal of Acoustics,1995,14(2):127-132.
6张伟,汪岳峰,董伟.微光像增强器噪声功率谱测试研究[J].光谱学与光谱分析,2003,23(3):621-622. 被引量：3
7CHEN Jing, LIU Litian, LI Zhijian, TAN Zhimin (Institute of Microelectronics, Tsinghua University Beijing 100084) MA Jun, LI Boquan (Institute of Acoustics, Chinese Academy of Sciences Beijing 100080).Design and fabrication of a silicon miniature condenser microphone[J].Chinese Journal of Acoustics,2001,20(2):130-138.
8Jie Cheng CHEN,Da Shah FAN,Xiang Rong ZHU.Sharp L^2 Boundedness of the Oscillatory Hyper-Hilbert Transform along Curves[J].Acta Mathematica Sinica,English Series,2010,26(4):653-658. 被引量：7
9王晓慧,袁哲俊,张广玉.The Experimental Study of Micro-Tool Servo with Electrostrictive Actuator[J].Journal of Harbin Institute of Technology(New Series),1994,1(2):45-47.
10PZ 100 CAP： Compact Piezo Actuator Equipped With Capacitive Measurement System[J].光机电信息,2006,23(12):54-55.

Journal of Bionic Engineering

2015年第4期

浏览历史

内容加载中请稍等...