爬树机器人机构设计及运动分析
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摘要
机器人是二十一世纪最具代表性的光机电一体化技术系统。工业机器人在现代化工业国家正在得到越来越广泛的应用,各种工业机器人的商品样机不断进入市场,在这种情况下,模拟工业机器人来开发各种各样的机器人是一个很需要重视的领域,它作为机器人技术、计算机技术和机电一体化技术教育的教学工具,对人才培养和高新技术的推广应用有着重要的意义。
本文介绍了国内外爬树机器人的发展状况,并对其进行了功能原理分析,在总结国内外爬树机器人现状的基础上,对爬树机器人进行了机构设计和理论分析。
本文对爬树机器人进行了两套方案设计,通过方案对比分析,采用曲柄滑块结构,实现爬树过程。该爬树机器人机构设计采用曲柄滑块机构、凸轮机构等实现机器人的爬树过程;选择了步进电机作为驱动电机;确定了曲柄、连杆构件的尺寸,描述了活动卡爪和槽型凸轮的工作原理,并对爬树机器人进行了动画演示;根据曲柄滑块的工作原理对爬树机器人进行运动分析和仿真;分析了爬树机器人的控制系统,并介绍了各个控制部分工作原理和特点,绘制了爬树机器人的控制系统流程图。该爬树机器人采用计算机控制装置,运用分级式控制方式,由PC机、上位单片机和下位单片机构成三级控制系统。设计了控制系统的硬件电路图及软件流程图。
Robot is the most representative system of mechatronics technology in the 21th Century . Industrial robot is being more and more widely used in modern industrial countries , Many merchandise prototypes of industrial robot are eutenhg into market continuously ,in this condition using stimulant industrial robot to explore all kinds of robot is a very important field. As the teaching means of robot technology、computer technology and mechatronics technology , industrial robot plays an important role in cultivating talents as well as generalizing and applying high technology.
In this article ,present situation and development of climbing tree robot are introduced ,at the same time its principle is analyzed. After Summarizing the present situation of climbing tree robot at home and abrod ,mechanism design and theoretical analysis of climbing tree robot are finished.
Two designs of scheme are applied in climbing tree robot.By comparing the two designs of scheme , crank block design and cam mechanism are used to realize the process of climbing tree, stepper motor drives organization, whivh and connecting bar are fixed on the principles of work of movable jaw and channel cam are described,animation show of climbing tree robot is implemented ;basing on principle of work of crank block,motion analysis and emulation of climbing tree . robot are executed;the control system of climbing tree robot analysised,futher,each principle of work and trait of control system is introduced ,at the same time,control system flow chart of climbing tree robot is drew. The climbing tree robotis controlled by computer,adopt hierarchical control, control system includes PC,epigyny single chip and hypogyny single chip,simultaneously,its hardware circuit diagram and software flow patterm are designed.
本文介绍了国内外爬树机器人的发展状况,并对其进行了功能原理分析,在总结国内外爬树机器人现状的基础上,对爬树机器人进行了机构设计和理论分析。
本文对爬树机器人进行了两套方案设计,通过方案对比分析,采用曲柄滑块结构,实现爬树过程。该爬树机器人机构设计采用曲柄滑块机构、凸轮机构等实现机器人的爬树过程;选择了步进电机作为驱动电机;确定了曲柄、连杆构件的尺寸,描述了活动卡爪和槽型凸轮的工作原理,并对爬树机器人进行了动画演示;根据曲柄滑块的工作原理对爬树机器人进行运动分析和仿真;分析了爬树机器人的控制系统,并介绍了各个控制部分工作原理和特点,绘制了爬树机器人的控制系统流程图。该爬树机器人采用计算机控制装置,运用分级式控制方式,由PC机、上位单片机和下位单片机构成三级控制系统。设计了控制系统的硬件电路图及软件流程图。
Robot is the most representative system of mechatronics technology in the 21th Century . Industrial robot is being more and more widely used in modern industrial countries , Many merchandise prototypes of industrial robot are eutenhg into market continuously ,in this condition using stimulant industrial robot to explore all kinds of robot is a very important field. As the teaching means of robot technology、computer technology and mechatronics technology , industrial robot plays an important role in cultivating talents as well as generalizing and applying high technology.
In this article ,present situation and development of climbing tree robot are introduced ,at the same time its principle is analyzed. After Summarizing the present situation of climbing tree robot at home and abrod ,mechanism design and theoretical analysis of climbing tree robot are finished.
Two designs of scheme are applied in climbing tree robot.By comparing the two designs of scheme , crank block design and cam mechanism are used to realize the process of climbing tree, stepper motor drives organization, whivh and connecting bar are fixed on the principles of work of movable jaw and channel cam are described,animation show of climbing tree robot is implemented ;basing on principle of work of crank block,motion analysis and emulation of climbing tree . robot are executed;the control system of climbing tree robot analysised,futher,each principle of work and trait of control system is introduced ,at the same time,control system flow chart of climbing tree robot is drew. The climbing tree robotis controlled by computer,adopt hierarchical control, control system includes PC,epigyny single chip and hypogyny single chip,simultaneously,its hardware circuit diagram and software flow patterm are designed.
引文
[1] 黄善钧.壁面移动机器人的研究.哈工大七十周年校庆增刊,1990
[2] 柳洪义.机器人技术基础.2002.冶金工业出版社.165~166
[3] 王炎,周大成.移动式服务机器人的发展现状及我们的研究.电气传动.2004.4:3~7
[4] 冯建农,柳明,吴捷.自主移动机器人智能导航研究进展.机器人.1997,19(6):468~478
[5] 863计划智能机器人主题专家组.862谋划对中国机器人发展的巨大作用和深远影响.机器人技术与应用.2001,14(3):4~14
[6] 汪云涛,吴林.移动式智能服务机器人的现状.机器人增刊.1998,20:11~15
[7] 赖维德 工业机器人技术 第四课
[8] 王巍,梁斌,强文义.月球探测机器人及其关键技术浅析.哈尔滨工业大学学报.2001,33(3):321~325
[9] 蔡自兴.机器人学.清华大学出版社,2000
[10] 刘振山.自主移动机器人运动控制系统的设计与实现人.研究生硕士学位论文.2004:3~6
[11] 王旭东,梁斌,吴宏鑫等.面向21世纪的我国遥科学空间机器人发展的建议.空间机器人及遥科学技术研讨会论文集.1999
[12] 刘方湖,陈建平,马培荪,曹志奎.行星探测机器人的研究现状和发展趋势.机器人.2002,24(3):268~275
[13] 蒋新松.未来机器人技术发展方向的探讨.机器人.1996,18(5):285~291
[14] Bayoum I M M, Chen J. A Hierarchical Multiview-based Hypothesizing Approach for 3D Robot Vision. International Journal of Robotics and Automation.
[15] 欧阳正柱,何克忠.GPS在智能移动机器人中的应用.微计算机信息.2001.11
[16] Yong c Cao, Hyung S Cho, A Stereo Vision-based Obstacle Detecting method for Mobile Robot Navigation, Robotica, 1994, 12
[17] Christoher E Smith, Scott A Brandt, Nkolaos P Papanikolopoulos. Vision Sensing for Intelligent Vehicle and Higway Systems. (MFT)94
[18] Kar-Tai Song, Wen-Hui tang, Environment Recognition for a Mobile Robot Using Double Ultrasonic Sensor and a CCD Camera. (MFT)94
[19] Murray R, M, Sastry S. S. Nonholonomic motion planning: Steering using sinusolids. IEEET rans. Automatic Control. 1993, 38(5): 700-716
[20] D'Andrea-Novel B, Campion G and Bastin G Control of Nonholonolmic Wheeled Mobile Robots by State Feedback Linearization. Int. J. robotics Research. 1995, 14(6): 543~559
[21] Samson C, Ait-Abderrahim K. Feedback Control of Nonholonimic Wheeled Car in Cartesian Space. Proc. IEEET Int. Conf. On Robot and Automat, 1991, 1136~1141
[22] 赵新华,曹作良.可移动机器人运动学模型与控制原理.机器人.1994,16(4):215~218
[23] Gtacttinger TJ, Ktagh B H. Evaluation and time-scaling of trajectories for whelled mobile robots. Trans ASME J of Dynam Syat Meas Control. 1989, 111(2): 222~231
[24] 李世华,田玉平.非完整移动机器人的轨迹跟踪控制.控制与决策.2002,17(3):302~305
[25] Heami A, Mehrabi M G, Cheng R M H. Synthesis of an optimal conteol law for path tracking in mobile robots. Automatica, 1992, 28(2): 383~387
[26] 柳长安,李国栋,刘春阳.差动驱动式移动机器人的运动规划.哈尔滨工业大学学报.2003,35(9):1096~1101
[27] SERJIH. A unified approach to motion control of mobile manipulatiors [J]. The International Journal of Robotics research. 1998, 17(2): 10~15
[28] 蔡自兴.机器人学.清华大学出版社,2000,9
[29] 熊有伦等.机器人学.机械工业出版社.1990
[30] 许波.MatLad.工程数学应用.清华大学出版社.2000.4
[31] 马香峰,余达太.工业机器人的操作机设计.冶金工业出版社.1999
[32] 叶长龙.硕士学位论文.工业机器人的运动学及动力学研究.37~43
[33] 罗洪量主编.《机械原理课程设计指导书》(第二版).北京:高等教育出版社.1986年
[34] JJ.杰克(美)主编.《机械与机构的设计原理》(第一版).北京:机械工业出版社.1985年
[35] 王玉新主编.《机构创新设计方法学》(第一版).天津:天津大学出版社.1996年
[36] 孙恒,陈作模主编.《机械原理》(第六版).北京:高等教育出版社,2001
[2] 柳洪义.机器人技术基础.2002.冶金工业出版社.165~166
[3] 王炎,周大成.移动式服务机器人的发展现状及我们的研究.电气传动.2004.4:3~7
[4] 冯建农,柳明,吴捷.自主移动机器人智能导航研究进展.机器人.1997,19(6):468~478
[5] 863计划智能机器人主题专家组.862谋划对中国机器人发展的巨大作用和深远影响.机器人技术与应用.2001,14(3):4~14
[6] 汪云涛,吴林.移动式智能服务机器人的现状.机器人增刊.1998,20:11~15
[7] 赖维德 工业机器人技术 第四课
[8] 王巍,梁斌,强文义.月球探测机器人及其关键技术浅析.哈尔滨工业大学学报.2001,33(3):321~325
[9] 蔡自兴.机器人学.清华大学出版社,2000
[10] 刘振山.自主移动机器人运动控制系统的设计与实现人.研究生硕士学位论文.2004:3~6
[11] 王旭东,梁斌,吴宏鑫等.面向21世纪的我国遥科学空间机器人发展的建议.空间机器人及遥科学技术研讨会论文集.1999
[12] 刘方湖,陈建平,马培荪,曹志奎.行星探测机器人的研究现状和发展趋势.机器人.2002,24(3):268~275
[13] 蒋新松.未来机器人技术发展方向的探讨.机器人.1996,18(5):285~291
[14] Bayoum I M M, Chen J. A Hierarchical Multiview-based Hypothesizing Approach for 3D Robot Vision. International Journal of Robotics and Automation.
[15] 欧阳正柱,何克忠.GPS在智能移动机器人中的应用.微计算机信息.2001.11
[16] Yong c Cao, Hyung S Cho, A Stereo Vision-based Obstacle Detecting method for Mobile Robot Navigation, Robotica, 1994, 12
[17] Christoher E Smith, Scott A Brandt, Nkolaos P Papanikolopoulos. Vision Sensing for Intelligent Vehicle and Higway Systems. (MFT)94
[18] Kar-Tai Song, Wen-Hui tang, Environment Recognition for a Mobile Robot Using Double Ultrasonic Sensor and a CCD Camera. (MFT)94
[19] Murray R, M, Sastry S. S. Nonholonomic motion planning: Steering using sinusolids. IEEET rans. Automatic Control. 1993, 38(5): 700-716
[20] D'Andrea-Novel B, Campion G and Bastin G Control of Nonholonolmic Wheeled Mobile Robots by State Feedback Linearization. Int. J. robotics Research. 1995, 14(6): 543~559
[21] Samson C, Ait-Abderrahim K. Feedback Control of Nonholonimic Wheeled Car in Cartesian Space. Proc. IEEET Int. Conf. On Robot and Automat, 1991, 1136~1141
[22] 赵新华,曹作良.可移动机器人运动学模型与控制原理.机器人.1994,16(4):215~218
[23] Gtacttinger TJ, Ktagh B H. Evaluation and time-scaling of trajectories for whelled mobile robots. Trans ASME J of Dynam Syat Meas Control. 1989, 111(2): 222~231
[24] 李世华,田玉平.非完整移动机器人的轨迹跟踪控制.控制与决策.2002,17(3):302~305
[25] Heami A, Mehrabi M G, Cheng R M H. Synthesis of an optimal conteol law for path tracking in mobile robots. Automatica, 1992, 28(2): 383~387
[26] 柳长安,李国栋,刘春阳.差动驱动式移动机器人的运动规划.哈尔滨工业大学学报.2003,35(9):1096~1101
[27] SERJIH. A unified approach to motion control of mobile manipulatiors [J]. The International Journal of Robotics research. 1998, 17(2): 10~15
[28] 蔡自兴.机器人学.清华大学出版社,2000,9
[29] 熊有伦等.机器人学.机械工业出版社.1990
[30] 许波.MatLad.工程数学应用.清华大学出版社.2000.4
[31] 马香峰,余达太.工业机器人的操作机设计.冶金工业出版社.1999
[32] 叶长龙.硕士学位论文.工业机器人的运动学及动力学研究.37~43
[33] 罗洪量主编.《机械原理课程设计指导书》(第二版).北京:高等教育出版社.1986年
[34] JJ.杰克(美)主编.《机械与机构的设计原理》(第一版).北京:机械工业出版社.1985年
[35] 王玉新主编.《机构创新设计方法学》(第一版).天津:天津大学出版社.1996年
[36] 孙恒,陈作模主编.《机械原理》(第六版).北京:高等教育出版社,2001