串联机器人可控阻尼半主动控制的基础研究
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摘要
近年来,以工业机器人为代表的串联机器人得到了广泛的应用,尤其在自动化程度很高的生产线上,串联机器人更是成为代替重复单调劳动力、提高生产效率和产品质量的重要途径。随着串联机器人在航空航天、精密制造等领域的逐渐应用,轻质、高速、高机动性将成为其发展的一个重要方向。但由此造成的低频机械振动、末端定位精度下降等问题,则成为这类串联机器人需要解决的关键问题。
本文在研究三自由度串联机器人运动方程,以及磁流变阻尼器动力学模型和动态特性的基础上,通过对半主动控制方法和控制算法的研究,利用磁流变阻尼器,进行了三自由度串联机器人振动半主动控制的仿真与实验研究。本文的工作主要有以下几个方面:
(1)在广泛阅读文献的基础上,了解振动控制方面的基本知识,确定进行串联机器人振动控制的半主动控制方法及其算法;
(2)对三自由度串联机器人进行建模,并通过数学方法解出其垂直方向振动与阻尼系数之间的关系;
(3)介绍磁流变液的磁流变效应与磁流变阻尼器的工作模式及其动力学模型,探讨磁流变阻尼器主要参数之间的关系,利用数据拟合的方法求出磁流变阻尼器阻尼系数与输入电流之间的关系;
(4)根据三自由度串联机器人数学模型与磁流变阻尼器力学模型,建立振动半主动控制系统的Simulink仿真程序,通过双态控制和模糊控制进行机器人的振动控制仿真研究,并比较这两种控制算法的控制效果;
(5)进行串联机器人实验模型振动半主动控制系统的实验研究,验证其控制效果。
In recent years, serial robot represented by industrial robot has got a wide range of applications. Especially in highly automated production line, serial robot has become an important way to replace monotonous labor, increase production efficiency and product quality. With the gradual application in aerospace, precision manufacturing, and other areas, lightweight, high-speed, and high mobility will become an important development direction of serial robot. But the resulting problems, such as low-frequency mechanical vibration and the loss of positioning, are becoming the bottleneck for this kind of serial robot to development.
This paper uses MR damper to do vibration control of the serial robot experimental model through researching the semi-active control method and control algorithm, which is based on the mathematics model of 3-DOF serial robot, as well as studying dynamic model and dynamic response of MR damper. This work mainly consists of the following aspects:
(1) Based on the widely read documents, this paper narrates the basics of vibration control, and ascertains the semi-active control method and its algorithm to control vibration of serial robot;
(2) 3-DOF Serial robot experimental model designed is modeled, and the relationship between the vertical vibration and damping coefficient of the model is got through mathematical method;
(3) This paper does a study of the magnetic effect of MR fluid damper and the work pattern and dynamic model of MR damper, discusses the relationship of the main parameters of MR damper, and then determines the relationship between the damper damping coefficient and input current by fitting method of data;
(4) According to the 3-DOF serial robot the mathematics model and MR damper dynamic model, this paper builds the Simulink simulation block diagram of control system, proceeds the robot model's control simulation through the two-state control and fuzzy control, and compares the control effect of these two control algorithms;
(5) The experimental study of vibration semi-active control system of the serial robot test model is done to verify the control effect.
本文在研究三自由度串联机器人运动方程,以及磁流变阻尼器动力学模型和动态特性的基础上,通过对半主动控制方法和控制算法的研究,利用磁流变阻尼器,进行了三自由度串联机器人振动半主动控制的仿真与实验研究。本文的工作主要有以下几个方面:
(1)在广泛阅读文献的基础上,了解振动控制方面的基本知识,确定进行串联机器人振动控制的半主动控制方法及其算法;
(2)对三自由度串联机器人进行建模,并通过数学方法解出其垂直方向振动与阻尼系数之间的关系;
(3)介绍磁流变液的磁流变效应与磁流变阻尼器的工作模式及其动力学模型,探讨磁流变阻尼器主要参数之间的关系,利用数据拟合的方法求出磁流变阻尼器阻尼系数与输入电流之间的关系;
(4)根据三自由度串联机器人数学模型与磁流变阻尼器力学模型,建立振动半主动控制系统的Simulink仿真程序,通过双态控制和模糊控制进行机器人的振动控制仿真研究,并比较这两种控制算法的控制效果;
(5)进行串联机器人实验模型振动半主动控制系统的实验研究,验证其控制效果。
In recent years, serial robot represented by industrial robot has got a wide range of applications. Especially in highly automated production line, serial robot has become an important way to replace monotonous labor, increase production efficiency and product quality. With the gradual application in aerospace, precision manufacturing, and other areas, lightweight, high-speed, and high mobility will become an important development direction of serial robot. But the resulting problems, such as low-frequency mechanical vibration and the loss of positioning, are becoming the bottleneck for this kind of serial robot to development.
This paper uses MR damper to do vibration control of the serial robot experimental model through researching the semi-active control method and control algorithm, which is based on the mathematics model of 3-DOF serial robot, as well as studying dynamic model and dynamic response of MR damper. This work mainly consists of the following aspects:
(1) Based on the widely read documents, this paper narrates the basics of vibration control, and ascertains the semi-active control method and its algorithm to control vibration of serial robot;
(2) 3-DOF Serial robot experimental model designed is modeled, and the relationship between the vertical vibration and damping coefficient of the model is got through mathematical method;
(3) This paper does a study of the magnetic effect of MR fluid damper and the work pattern and dynamic model of MR damper, discusses the relationship of the main parameters of MR damper, and then determines the relationship between the damper damping coefficient and input current by fitting method of data;
(4) According to the 3-DOF serial robot the mathematics model and MR damper dynamic model, this paper builds the Simulink simulation block diagram of control system, proceeds the robot model's control simulation through the two-state control and fuzzy control, and compares the control effect of these two control algorithms;
(5) The experimental study of vibration semi-active control system of the serial robot test model is done to verify the control effect.
引文
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2.朱世强,王宣银.机器人技术及其应用[M],浙江:浙江大学出版社,2007,2-13.
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9.范子杰,庄继德,卢秉恒.粘弹性阻尼材料在柔性机械手振动控制中应用的实验研究[J],机器人,1992,14(3):1-4.
10.王兴松,朱建.用加速度波形优化方法减少柔性机械臂参与振动[J],机械工程学报,2001,37(8):10-13.
11.宋志民,余跃庆,张策等.柔性冗余度机器人振动主动控制[J],机械科学与技术,2002,21(2):210-213.
12.谢伟.磁流变阻尼器及其结构振动控制研究[D],武汉:话中科技大学,2007.
13.郑艳萍,赵江铭,刘旭辉等.磁流变液减振器及振动控制技术研究[J],煤矿机械,2007,28(9):58-60.
14. Ou Jinping, Wu Bo, Song T.T.. Recent advances in research on and applications of passive energy dissipation system [J], Earthquake Engineering and Engineering Vibration,1996, 16(3):72-96.
15.赵斌,吴敏哲,梅占馨.基础隔振减小建筑顶部附属物动力反应的原理分析[J],西安建筑科技大学学报,1999,31(3):225-228.
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17.刘旭辉.磁流变液减震器及其振动控制的研究[D],天津:天津理工大学,2006.
18. Song T.T., Constantionou M.C.. Passive and Active Structural Vibration Control in Civil Engineering [J], CISM Undine,1994.
19.王玲玲,李耀刚,陈冠国.振动主动控制技术的研究现状及发展趋势[J],农机化研究,2005,9(5):30-32.
20.李敏霞,刘季.主动结构控制算法综述[J],世界地震工程,1998,14(4):61-69.
21.顾仲权,马扣根,陈卫东.振动主动控制[J],北京:国防工业出本社,1997.
22.吕西林,叶骅.结构主动控制和混合控制技术的新发展[J],世界地震工程,1997,13(2):21-29.
23.桂国庆.结构控制技术发展现状与展望[J],南昌大学学报,1994,16(4):17-24.
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25.金玉杰.半主动控制技术的应用发展状[J],吉林建筑工程学院学报,2005,22(4):48-50.
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27.李英华,李桂荣.振动控制的发展及趋势[J],云南农业大学学报,2001,16(1):77-81.
28.刘松国.六自由度串联机器人运动优化与轨迹跟踪控制研究[D],杭州:浙江大学,2009.
29.刘其端.六轴串联机器人控制工程系统软件设计与实现[D],哈尔滨:哈尔滨工程大学,2008.
30. Chien-Yu Ji, Tsung-Chien Chen and Yung-Lung Lee. Joint control for flexible-joint robot with input-estimation approach and LQR control [J], Optimal Control Applications and Methods,2008,29:101-125.
31.胡海岩.振动控制基础[M],北京:北京航空航天大学出版社,2005:19-80.
32.赵林.结构振动半主动控制的实用性研究[J],工程抗震与加固改造,2005,27(2):32-39.
33.李敏霞,刘季.变刚度半主动结构振动控制的实验研究[J],地震工程与工程振动,1998,18(4):90-95.
34.蒙文流,韦树英,罗会来.半主动控制的研究现状及其工程应用[J],广西科学院学报,2008,24(3):231-237.
35.杨润林,周锡元,闫维明等.结构半主动变阻尼控制性能评估[J],振动与冲击,2007,26(3):37-42.
36.赵大海,李宏男.采用模糊逻辑的半主动摩擦阻尼器对偏心结构的振动控制[J],振动工程学报,2007,20(2):112-117.
37.韩兵康,杜冬.结构半主动调谐质量阻尼器的发展[J],振动与冲击,2005,24(2):46-50.
38.熊俊明,梁启智.可控调谐液体阻尼器动力响应的数值模拟[J],噪声与振动控制,2002,2:3-6.
39.熊俊明.可控调谐液体阻尼器系统对高层建筑地震反应控制的研究[D],广州:华南理工大学,2001.
40.李彦.基于磁流变阻尼器的半主动振动控制[D],北京:清华大学,2008.
41.周云,谭平.磁流变阻尼控制理论与技术[M],北京:科学出版社,2007:110-140,71-90.
42.李宏南,阎石,林皋.智能结构控制发展综述[J],地震工程与工程振动,1999,19(2):29-36.
43.阎石.结构振动智能控制的人工神经网络与模糊逻辑方法研究[D],大连:大连理工大学,2000.
44.江建晓,孟光.磁流变液研究进展[J],航空学报,2002,23(1):6-12.
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2.朱世强,王宣银.机器人技术及其应用[M],浙江:浙江大学出版社,2007,2-13.
3.神原伸介,张炜.日本工业机器人最新发展动向[J],机器人技术与应用,2008,4:23-25.
4.胡小锋,于建国,叶庆泰等.接触式传感器对柔性机械手振动控制系统性能的影响[J],振动与冲击,1992,14(3):37-40.
5.刘迎春,余跃庆,姜春福.柔性机器人研究现状[J],机械设计,2003,20(12):4-8.
6. Fukda T. Flexibility control of elastic robot arms [J]. Journal of robotic systems,1985.
7. Cannon R H, Schmitz E. Precise control of flexible manipulators [M]. Robotics Research, MIT Press,1983,35-48.
8.宋秩民,余跃庆,张策等.柔性机器人动力学分析与振动控制研究综述[J],机械设计,2003,20(4):1-5.
9.范子杰,庄继德,卢秉恒.粘弹性阻尼材料在柔性机械手振动控制中应用的实验研究[J],机器人,1992,14(3):1-4.
10.王兴松,朱建.用加速度波形优化方法减少柔性机械臂参与振动[J],机械工程学报,2001,37(8):10-13.
11.宋志民,余跃庆,张策等.柔性冗余度机器人振动主动控制[J],机械科学与技术,2002,21(2):210-213.
12.谢伟.磁流变阻尼器及其结构振动控制研究[D],武汉:话中科技大学,2007.
13.郑艳萍,赵江铭,刘旭辉等.磁流变液减振器及振动控制技术研究[J],煤矿机械,2007,28(9):58-60.
14. Ou Jinping, Wu Bo, Song T.T.. Recent advances in research on and applications of passive energy dissipation system [J], Earthquake Engineering and Engineering Vibration,1996, 16(3):72-96.
15.赵斌,吴敏哲,梅占馨.基础隔振减小建筑顶部附属物动力反应的原理分析[J],西安建筑科技大学学报,1999,31(3):225-228.
16.李宏男,阎石.中国结构控制的研究与应用[J],地震工程与工程振动,1999,19(1): 107-117.
17.刘旭辉.磁流变液减震器及其振动控制的研究[D],天津:天津理工大学,2006.
18. Song T.T., Constantionou M.C.. Passive and Active Structural Vibration Control in Civil Engineering [J], CISM Undine,1994.
19.王玲玲,李耀刚,陈冠国.振动主动控制技术的研究现状及发展趋势[J],农机化研究,2005,9(5):30-32.
20.李敏霞,刘季.主动结构控制算法综述[J],世界地震工程,1998,14(4):61-69.
21.顾仲权,马扣根,陈卫东.振动主动控制[J],北京:国防工业出本社,1997.
22.吕西林,叶骅.结构主动控制和混合控制技术的新发展[J],世界地震工程,1997,13(2):21-29.
23.桂国庆.结构控制技术发展现状与展望[J],南昌大学学报,1994,16(4):17-24.
24.潘海兵,刘晋浩,赵文锐.混合振动控制的研究[J],煤矿机械,2008,29(12):11-12.
25.金玉杰.半主动控制技术的应用发展状[J],吉林建筑工程学院学报,2005,22(4):48-50.
26. Kobori T., Takahashi M. Seismic response controlled structure with the variable stiffness system [J], Earthquake Engineering and Structure Dynamics,1993,22(9):25-41.
27.李英华,李桂荣.振动控制的发展及趋势[J],云南农业大学学报,2001,16(1):77-81.
28.刘松国.六自由度串联机器人运动优化与轨迹跟踪控制研究[D],杭州:浙江大学,2009.
29.刘其端.六轴串联机器人控制工程系统软件设计与实现[D],哈尔滨:哈尔滨工程大学,2008.
30. Chien-Yu Ji, Tsung-Chien Chen and Yung-Lung Lee. Joint control for flexible-joint robot with input-estimation approach and LQR control [J], Optimal Control Applications and Methods,2008,29:101-125.
31.胡海岩.振动控制基础[M],北京:北京航空航天大学出版社,2005:19-80.
32.赵林.结构振动半主动控制的实用性研究[J],工程抗震与加固改造,2005,27(2):32-39.
33.李敏霞,刘季.变刚度半主动结构振动控制的实验研究[J],地震工程与工程振动,1998,18(4):90-95.
34.蒙文流,韦树英,罗会来.半主动控制的研究现状及其工程应用[J],广西科学院学报,2008,24(3):231-237.
35.杨润林,周锡元,闫维明等.结构半主动变阻尼控制性能评估[J],振动与冲击,2007,26(3):37-42.
36.赵大海,李宏男.采用模糊逻辑的半主动摩擦阻尼器对偏心结构的振动控制[J],振动工程学报,2007,20(2):112-117.
37.韩兵康,杜冬.结构半主动调谐质量阻尼器的发展[J],振动与冲击,2005,24(2):46-50.
38.熊俊明,梁启智.可控调谐液体阻尼器动力响应的数值模拟[J],噪声与振动控制,2002,2:3-6.
39.熊俊明.可控调谐液体阻尼器系统对高层建筑地震反应控制的研究[D],广州:华南理工大学,2001.
40.李彦.基于磁流变阻尼器的半主动振动控制[D],北京:清华大学,2008.
41.周云,谭平.磁流变阻尼控制理论与技术[M],北京:科学出版社,2007:110-140,71-90.
42.李宏南,阎石,林皋.智能结构控制发展综述[J],地震工程与工程振动,1999,19(2):29-36.
43.阎石.结构振动智能控制的人工神经网络与模糊逻辑方法研究[D],大连:大连理工大学,2000.
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