打磨机器人手臂的三维设计与静动态分析
摘要
机器人是一种典型的机电一体化设备,集运动学与动力学理论、机械设计与制造技术、计算机硬软件技术、控制理论、传感器技术、人工智能理论等科学及技术于一体,广泛应用于工业生产、太空和海洋探索、国防技术等领域。在固体火箭发动机壳体制造过程中,壳体内部由于制造工艺的限制,有一层很薄的脱粘层,而该脱粘层必须清除,以避免影响以后的加工过程。传统的打磨工作是手工完成的,不仅打磨效率极为低下,而且粉尘对工作人员的健康极为不利。为了提高生产效率及改善作业环境,我们研制了打磨机器人,以实现打磨过程的自动化、智能化。
打磨机器人是一台四自由度的移动机器人。本体设计由轮式移动机构设计和机械臂设计组成,其中本论文不涉及轮式移动机构设计。机械臂模仿人的手臂设计成三个自由度,末端执行器采用柔性与刚性相结合的结构,通过调整各关节角可使机器人对空间一定范围内的目标进行打磨。首先,对机器人自动规划技术进行了研究,以“打磨机器人”规划系统为例,详细阐述了机器人操作任务和工作环境模型的表述,操作任务分解原理,子任务的求解与实现方法。并对机器人进行运动学分析,确定了臂部的关键参数。
其次,以Pro/E软件为基础,对打磨机器人手臂结构进行设计,包括关键参数的确定与优化,分别建立了大臂、小臂和腕部的实体模型,对小臂和腕部的传动方式进行选择,并最终确定为链传动。
最后,为了检验机器人手臂各部分结构设计和规划结果的合理性,将Pro/E建立好的实体模型导入ANSYS中,进行强度、刚度分析,分别确定应力最大和变形量最大发生的部位。接着在ANSYS中对手臂进行动力学分析,包括模态、谐响应和瞬态分析,确定手臂的固有频率和手臂在受到不定载荷激励下的振动及变形情况。
Robot technique as a synthesis system, which includes kinematics and dynamics theory, machine design and manufacture, computer hardware and software, control theory, sensor technology, artificial intelligence and so on, is widely used in scope of industrial production, exploration of the space and the sea, national defense etc. In the process of the manufacturing of the shell of solid rocket, there is a thin inadhesion layer on the insider shell. And we have to scrape off the layer because it is in the way of the later manufacturing process. The milling work was done by hand before. It's not only inefficient, but also harmful to the workers'health because of the dust. In order to solve these problems, we have developed this polishing robot.
Polishing robot is a moving robot with four DOF. The job contains wheel structure and mechanical arm design, and this paper doesn't involve wheel structure. The arm has 3 degrees like human arm, and end offector with flexible and rigidity frame can polish the target through adjusting the angle of joints. Firstly, Robot automate planning technology is researched deeply in this paper. The polishing robot planning system is described as an example, including modeling of assignment and working condition, operate assignment decomposing principle, solving and realizing of sub-assignment. And through kinematics analysis of robot, the key parameters of arm is designed.
Secondly, based on the Pro/E software, we have designed the arm of polishing robot, including the determination and optimization of key parameters, and designed the solid models of big arm, small arm and wrist. Then chosen the transmission method of small arm and wrist, and identified as chain drive.
Finally, in order to check the rationality of machinery design and planning result, this paper transmits the solid model from Pro/E to ANSYS for the analysis of intensity and rigidity, and find out the sites of the maximum stress and the maximum deformation. Then this paper performs the dynamic analysis of arm, including modal, harmonic and transient, which help to determine the nature frequency of arm and the vibration and deformation states with uncertain loading incentives of arm.
打磨机器人是一台四自由度的移动机器人。本体设计由轮式移动机构设计和机械臂设计组成,其中本论文不涉及轮式移动机构设计。机械臂模仿人的手臂设计成三个自由度,末端执行器采用柔性与刚性相结合的结构,通过调整各关节角可使机器人对空间一定范围内的目标进行打磨。首先,对机器人自动规划技术进行了研究,以“打磨机器人”规划系统为例,详细阐述了机器人操作任务和工作环境模型的表述,操作任务分解原理,子任务的求解与实现方法。并对机器人进行运动学分析,确定了臂部的关键参数。
其次,以Pro/E软件为基础,对打磨机器人手臂结构进行设计,包括关键参数的确定与优化,分别建立了大臂、小臂和腕部的实体模型,对小臂和腕部的传动方式进行选择,并最终确定为链传动。
最后,为了检验机器人手臂各部分结构设计和规划结果的合理性,将Pro/E建立好的实体模型导入ANSYS中,进行强度、刚度分析,分别确定应力最大和变形量最大发生的部位。接着在ANSYS中对手臂进行动力学分析,包括模态、谐响应和瞬态分析,确定手臂的固有频率和手臂在受到不定载荷激励下的振动及变形情况。
Robot technique as a synthesis system, which includes kinematics and dynamics theory, machine design and manufacture, computer hardware and software, control theory, sensor technology, artificial intelligence and so on, is widely used in scope of industrial production, exploration of the space and the sea, national defense etc. In the process of the manufacturing of the shell of solid rocket, there is a thin inadhesion layer on the insider shell. And we have to scrape off the layer because it is in the way of the later manufacturing process. The milling work was done by hand before. It's not only inefficient, but also harmful to the workers'health because of the dust. In order to solve these problems, we have developed this polishing robot.
Polishing robot is a moving robot with four DOF. The job contains wheel structure and mechanical arm design, and this paper doesn't involve wheel structure. The arm has 3 degrees like human arm, and end offector with flexible and rigidity frame can polish the target through adjusting the angle of joints. Firstly, Robot automate planning technology is researched deeply in this paper. The polishing robot planning system is described as an example, including modeling of assignment and working condition, operate assignment decomposing principle, solving and realizing of sub-assignment. And through kinematics analysis of robot, the key parameters of arm is designed.
Secondly, based on the Pro/E software, we have designed the arm of polishing robot, including the determination and optimization of key parameters, and designed the solid models of big arm, small arm and wrist. Then chosen the transmission method of small arm and wrist, and identified as chain drive.
Finally, in order to check the rationality of machinery design and planning result, this paper transmits the solid model from Pro/E to ANSYS for the analysis of intensity and rigidity, and find out the sites of the maximum stress and the maximum deformation. Then this paper performs the dynamic analysis of arm, including modal, harmonic and transient, which help to determine the nature frequency of arm and the vibration and deformation states with uncertain loading incentives of arm.
引文
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2. Hongyi Liu. A study of gaits for the combined wheeled and legged vehicle 'robotrac'[J], Technical Report of Institute A of Mechanics, University of Stuttgart, No.01/1992,1992.
3. Hongyi Liu and Bangchun Wen. Efficient algorithum for force distribution of a combined wheeled and legged vehicle[J], Proc.Int.Conf.Adv.Rob., Tokyo,1993, pp.559-564.
4. Hongyi Liu, Weigang Song, and Bangchun Wen. Foot motion control of walking machines over rough terrain[J], Prof.Sec.Int.Conf.Motion and Vibration Control, Tokyo, 1994, pp.175-179.
5.柳洪义,宋伟刚.机器人技术基础[M],北京:冶金工业出版社,2002.
6.柳洪义,闻邦椿.一类轮腿结合式步行机的最优稳定裕度问题[J],东北大学学报,1994,15(2):162-165.
7.柳洪义,宋伟刚.自动贴瓷砖机器人系统[J],机器人技术与应用,2002,4:32-33.
8.柳洪义,于忠升.三峡升船机卷扬系统的静态仿真研究[J],矿山机械,1998,5:38-40.
9.Jorge Angeles(著),宋伟刚(译).机器人机械系统原理理论、方法和算法[M],北京:机械工业出版社,2004.
10.柳洪义,马现刚,朱树森.微波催化连续反应试验系统的温度控制[J],东北大学学报(自然科学版),2003,24(3):256-259.
11.刘杰,宋伟刚,李允公.机电一体化技术导论[M],北京:科学出版社,2006.
12.柳洪义,宋伟刚,彭兆行.控制步行机足运动的一种方法——修正组合摆线法[J],机器人,1994,16(6):350-356.
13.柳洪义,闻邦椿,H.斯欧格.一种轮腿结合式步行机的原路径步态[J],东北大学学报,1994,15(3):258-262.
14.马履中,周建忠.机器人与柔性控制系统[M],北京:化学工业出版社,2007.
15.John J.Craig(著),负超(译).机器人学导论[M],北京:机械工业出版社,2006.
16.郭洪红,贺继林,田宏宇,席巍.工业机器人技术[M],西安:西安电子科技大学出版社,2006.
17.孙树栋,王泽山,屠森林.工业机器人技术基础[M],西安:西北工业大学出版社,2006.
18.陈佩云,金茂青,曲忠萍.我国工业机器人发展现状[J],机器人技术与应用,2001,1:3-5.
19.孙斌,杨汝清.开放式机器人的控制器综述[J],机器人,2001,7:374-378.
20.王天然,曲道奎.工业机器人控制系统的开放体系结构[J],机器人,2002,5:256-261.
21.吴向阳,戴先中,孟正大.分布式机器人控制器体系结构的研究[J],东南大学学报(自然科学版),2003,9:200-204.
22.[日]白井良明.机器人工程[M],科学出版社OHM社,2001.
23.孙迪升,王炎.机器人控制技术[M],北京:机械工业出版社,1997.
24.黄鹤汀.金属切削机床上册[M],北京:机械工业出版社,1998.
25.张崇魏,李汉强.运动控制系统[M],武汉:武汉理工大学出版社,2002.1.
26.淡世哲,杨汝清.面向敏捷制造的机器人控制器体系结构的研究[J],机器人,2001,10:371-675.
27.徐华,贾培发,赵雁南.开放式机器人控制软件体系结构研究进展[J],高技术通讯,2003,1:100-105.
28.许兴华,铭辰,陶俐言.FMS中换刀机器人运动控制系统的实现研究[J],机械加工与自动化,2003,3:12-14.
29.王树国,付宜利.我国特种机器人发展战略思考[J],自动化学报,2002,12:70-76.
30.王树国,付宜利.特种机器人的基础科学问题和发展战略思考[J],中国科学基金,2002,5:269-273.
31.诸静.机器人控制技术[M],杭州:浙江大学出版社,1991.
32.谢存禧,李琳.空间机构设计与应用创新[M],北京:机械工业出版社,2008.
33.蔡自兴.机器人学[M],北京:清华大学出版社,2000.
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