管道内径在线检测机器人的研究
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摘要
基于对长距离管道在线检测的目的,在总结传统的管道在线检测机器人的基础上,利用管道中介质流动产生的驱动力,确定了一种新型管道内径在线检测机器人的设计方案,减少了机器人的动力源装置,使在线检测机器人设计简单化,降低了经济成本。
论文首先对管道内径在线检测机器人进行方案设计,经分析比较后提出了一种较佳方案,并根据此方案对机器人作了结构设计。
论文运用流体力学的知识对管道内径在线检测机器人的行走特性进行了研究,提出了使机器人在潜体状态下能够保持稳定运行的方法。用Pro/Engineer2001软件对机器人机构进行了三维实体建模,并运用动态仿真软件对机器人在管道变形处的运动情况了动态仿真,进一步验证了设计思想的正确性。
最后,研究了管道内径在线检测机器人的检测方法,给出了超声波测距的数据采集方法和数据通信的基本方案,为管道内径在线检测机器人系统的实现打下了坚实的基础。
A kind of new-type project on the robot measuring the internal diameter of the long distance pipeline online is put forward on the basis of summarizing the traditional robot measuring the pipeline online. The robot is driven by the power generated by the medium flowing in the pipeline, thus simplify the design and reduce the cost by cutting the dynamical equipment.
In this paper, the author present a kind of better scheme after analyzing and comparing the scheme on the pipeline robot of measuring the internal diameter online at first, then design the structure of the pipeline robot according to this scheme.
The author carry through the research on the stepped-characteristic of the robot using hydro-mechanical knowledge, put forward the method that make the robot can keep operating steadily under the state of diving the body. At the same time, build the three-dimensional entity's modeling of the structure of the robot using Pro/Engineer2001 software and complete the dynamic simulation of the movement state in the distortion position of the pipeline using dynamic simulate software, so the correctness of the design is proven.
Finally, The author study the robot-detection method of measuring the internal diameter of the pipeline online, describe the data acquisition method provided by ultrasonic wave and the basic scheme of data communication and lay a solid foundation for the realizing the robot-system of measuring the internal diameter of the pipeline online.
论文首先对管道内径在线检测机器人进行方案设计,经分析比较后提出了一种较佳方案,并根据此方案对机器人作了结构设计。
论文运用流体力学的知识对管道内径在线检测机器人的行走特性进行了研究,提出了使机器人在潜体状态下能够保持稳定运行的方法。用Pro/Engineer2001软件对机器人机构进行了三维实体建模,并运用动态仿真软件对机器人在管道变形处的运动情况了动态仿真,进一步验证了设计思想的正确性。
最后,研究了管道内径在线检测机器人的检测方法,给出了超声波测距的数据采集方法和数据通信的基本方案,为管道内径在线检测机器人系统的实现打下了坚实的基础。
A kind of new-type project on the robot measuring the internal diameter of the long distance pipeline online is put forward on the basis of summarizing the traditional robot measuring the pipeline online. The robot is driven by the power generated by the medium flowing in the pipeline, thus simplify the design and reduce the cost by cutting the dynamical equipment.
In this paper, the author present a kind of better scheme after analyzing and comparing the scheme on the pipeline robot of measuring the internal diameter online at first, then design the structure of the pipeline robot according to this scheme.
The author carry through the research on the stepped-characteristic of the robot using hydro-mechanical knowledge, put forward the method that make the robot can keep operating steadily under the state of diving the body. At the same time, build the three-dimensional entity's modeling of the structure of the robot using Pro/Engineer2001 software and complete the dynamic simulation of the movement state in the distortion position of the pipeline using dynamic simulate software, so the correctness of the design is proven.
Finally, The author study the robot-detection method of measuring the internal diameter of the pipeline online, describe the data acquisition method provided by ultrasonic wave and the basic scheme of data communication and lay a solid foundation for the realizing the robot-system of measuring the internal diameter of the pipeline online.
引文
[1] 付京逊等.机器人学.中国科学技术大学出版社,1989:2-40
[2] 周远清,张再兴.智能机器人系统.清华大学出版社,1989:50-60
[3] 王祚斌.国内外机器人发展概况,电气自动化,1995(2):64-65
[4] J.J.Craig.Introduction to Robotics:Mechanics&ControI.Addision-Wesley publishing Company. 1986:11-30
[5] 国家863计划智能机器人专家组.机器人博览,2001:3-4
[6] Allen.A.Pennington.Techniques Developed to Solve Problems of Unpiggable Lines.Pipe Line Industry. 1992(11):71-73
[7] 和田周平,木下源一郎.机器人技术.科学出版社.1983:9-31.
[8] 吉田政人.导管管厚检测开发NNK技报.1990,133:43-48
[9] 山田义漾.管内探测装置.日本钢管技报.1986,111:53-59
[10] Fukuda T, Kawamoto A, Arai F, et al. Mechanism and Swimmng Experiment of Micro Mobilr Robot in Water.Proceedings of IEEE Workshop on Micro Electro Mechanical Systems, 1994: 273-278
[11] Akahashi M,Hayashi I, et al.The Development of an In-pipe Microrobot Applying the Motion of an Earthworm. Journal of Precision Engineering,1995,61(1):90-94
[12] K.Taugnchi,N.Kawarazaki.Development of In-pipe Locomotion Robot.Proc of Fifth International Conference On Advanced Robotics. 1991,6,(1):297-302
[13] Kaneko,Makoto.Dynamic behavior of pipe inspection robot driven by fluid force. Transaction of the Japan Society of Mechanical Engineers.1997(7),63(611)partc:2368-2376
[14] Lan R Yarnell. Robot. United States Patent.No.4648454, 1987(5):22-76
[15] Takenorri Morimitsu et al. JSME.International.1988(31):37-41
[16] J.P.Coose et al. Robot Which Will Investigate The Condition of Underground Pipe. Final Report. 1986(5):87-209
[17] Kaneko makota. Dynamic behavior of pipe inspection robot driven by fluid force. Nippon Kikai Gakkai Ronbunshu, C Hen/Transactions of the Japan Society of Mechanical Engineers, Part C v 63 n 611 Jul 1997 JSME
[18] J.L.Cordell. In-line Inspection: What Technology is Best?.Pipeline & Industry.1991(7):47-48
[19] Jun Okamoto Jr. Autonomous System for Oil Pipelines Inspection.Elsevier Science,Mechatronics. 1999 (9): 731-743
[20] Norsk Elektro Optikk A/S.www.neo.no/idex.himl.2002
[21] 邓宗全.管内移动机器人产业化开发技术总报告.哈尔滨工业大学1996:21-25
[22] 吴林.世界机器人技术发展的新方向——特种机器人.中国宇航学会机器人学术年会.1990:1-3
[23] 邓宗全.注水管路用管内移动机器人技术总结报告。哈尔滨工业大学1994.5:1-12
[24] 邓宗全.管道机器人,《机器人技术与应用》,1996(6):12-14
[25] 邓宗全.管内作业机器人的发展与展望,《机器人》,1998(6):471-478
[26] 邓宗全.管内机器人研究中的几项新技术,《高技术通讯》,1994(5):12-14
[27] 张永顺.管内沙浆喷涂补口作业机器人技术及理论的研究.哈工大博士论文.1999.4.
[28] 姜生元.管内X射线探伤机器人技术及理论研究.哈工大博士论文.2001.4
[29] 周晓.管内移动机器人在弯管处的环境识别及控制技术研究.哈工大博士论文.1999.1
[30] 杨理践.漏磁法管道在线检测计算机系统.沈阳工业大学学报.1999.6:227-229.
[31] 贺辅云.油气输送管道电磁在线检测技术.合肥工业大学学报.2002.4:218-221
[32] 中国石油天然气管道技术公司.www.cnptc.com.2002
[33] 朱玉芳.小口径管道无缆型超声波检测系统总体设计及实验研究.南京理工大学硕士论文.2001.12
[34] 国务院关于石油天然气管道保护条例.2000.4
[35] 沈林福 关志民.我国研制成功高精度管道漏磁在线检测智能系统.科学时报.2002.1.8
[36] 朱敬德等.在役石油管道检测机器人机械设计.上海大学学报(自然科学版).Vol.7 NO.1:57-59
[37] 张英会等.弹簧手册.机械工业出版社.1997.6:174-246
[38] 张亮李云.流体力学.哈尔滨工程大学出版社.2001.6
[39] 茅春浦.流体力学.上海交通大学出版社.1995.12
[40] 胡敏良.流体力学.武汉工业大学出版社.2000.7.
[41] 蒋新松等.水下机器人.辽宁科学技术出版社2001.11
[42] 邢克飞.Pro/Engineer2001从入门到精通.西安电子科技大学出版社.2002.7
[43] 苏茜 刘莹.实战基础入门Pro/Engineer2001.中国铁道出版社.2002.9
[44] 李军 邢俊文等.ADAMS实例教程.北京理工大学出版社.2002.7
[45] 王国强 张进平等.虚拟样机技术及其在ADAMS上的实践.西北工业大学出版社.2002.3
[46] 郑健荣.ADAMS—虚拟样机技术入门与提高.机械工业出版社.2002.1
[47] George C Williamson, W Mark Bohon.Evaluation of ultrasonic intelligent pig performance:inherent technical problems as a pipeline inspection tool-part 1. CORROSOION PREVENTION&CONTROL. 1994.12:148-152
[48] [日]无损探伤学会编.超声波探伤A.第一版 南京:江苏科学技术出版社.1980
[49] 张玉清等.IBM PC微型计算机原理及接口技术.人民邮电出版社.1997.10
[50] M.Yoshida.K.Endo,N.Masuda, et al.Corrosion Inspection Pig for Gas Pipeline.NKK Technical Report. 1990,(133);43-48
[51] 王玉良等.微机原理与接口技术.北京邮电大学出版社.2001.6
[2] 周远清,张再兴.智能机器人系统.清华大学出版社,1989:50-60
[3] 王祚斌.国内外机器人发展概况,电气自动化,1995(2):64-65
[4] J.J.Craig.Introduction to Robotics:Mechanics&ControI.Addision-Wesley publishing Company. 1986:11-30
[5] 国家863计划智能机器人专家组.机器人博览,2001:3-4
[6] Allen.A.Pennington.Techniques Developed to Solve Problems of Unpiggable Lines.Pipe Line Industry. 1992(11):71-73
[7] 和田周平,木下源一郎.机器人技术.科学出版社.1983:9-31.
[8] 吉田政人.导管管厚检测开发NNK技报.1990,133:43-48
[9] 山田义漾.管内探测装置.日本钢管技报.1986,111:53-59
[10] Fukuda T, Kawamoto A, Arai F, et al. Mechanism and Swimmng Experiment of Micro Mobilr Robot in Water.Proceedings of IEEE Workshop on Micro Electro Mechanical Systems, 1994: 273-278
[11] Akahashi M,Hayashi I, et al.The Development of an In-pipe Microrobot Applying the Motion of an Earthworm. Journal of Precision Engineering,1995,61(1):90-94
[12] K.Taugnchi,N.Kawarazaki.Development of In-pipe Locomotion Robot.Proc of Fifth International Conference On Advanced Robotics. 1991,6,(1):297-302
[13] Kaneko,Makoto.Dynamic behavior of pipe inspection robot driven by fluid force. Transaction of the Japan Society of Mechanical Engineers.1997(7),63(611)partc:2368-2376
[14] Lan R Yarnell. Robot. United States Patent.No.4648454, 1987(5):22-76
[15] Takenorri Morimitsu et al. JSME.International.1988(31):37-41
[16] J.P.Coose et al. Robot Which Will Investigate The Condition of Underground Pipe. Final Report. 1986(5):87-209
[17] Kaneko makota. Dynamic behavior of pipe inspection robot driven by fluid force. Nippon Kikai Gakkai Ronbunshu, C Hen/Transactions of the Japan Society of Mechanical Engineers, Part C v 63 n 611 Jul 1997 JSME
[18] J.L.Cordell. In-line Inspection: What Technology is Best?.Pipeline & Industry.1991(7):47-48
[19] Jun Okamoto Jr. Autonomous System for Oil Pipelines Inspection.Elsevier Science,Mechatronics. 1999 (9): 731-743
[20] Norsk Elektro Optikk A/S.www.neo.no/idex.himl.2002
[21] 邓宗全.管内移动机器人产业化开发技术总报告.哈尔滨工业大学1996:21-25
[22] 吴林.世界机器人技术发展的新方向——特种机器人.中国宇航学会机器人学术年会.1990:1-3
[23] 邓宗全.注水管路用管内移动机器人技术总结报告。哈尔滨工业大学1994.5:1-12
[24] 邓宗全.管道机器人,《机器人技术与应用》,1996(6):12-14
[25] 邓宗全.管内作业机器人的发展与展望,《机器人》,1998(6):471-478
[26] 邓宗全.管内机器人研究中的几项新技术,《高技术通讯》,1994(5):12-14
[27] 张永顺.管内沙浆喷涂补口作业机器人技术及理论的研究.哈工大博士论文.1999.4.
[28] 姜生元.管内X射线探伤机器人技术及理论研究.哈工大博士论文.2001.4
[29] 周晓.管内移动机器人在弯管处的环境识别及控制技术研究.哈工大博士论文.1999.1
[30] 杨理践.漏磁法管道在线检测计算机系统.沈阳工业大学学报.1999.6:227-229.
[31] 贺辅云.油气输送管道电磁在线检测技术.合肥工业大学学报.2002.4:218-221
[32] 中国石油天然气管道技术公司.www.cnptc.com.2002
[33] 朱玉芳.小口径管道无缆型超声波检测系统总体设计及实验研究.南京理工大学硕士论文.2001.12
[34] 国务院关于石油天然气管道保护条例.2000.4
[35] 沈林福 关志民.我国研制成功高精度管道漏磁在线检测智能系统.科学时报.2002.1.8
[36] 朱敬德等.在役石油管道检测机器人机械设计.上海大学学报(自然科学版).Vol.7 NO.1:57-59
[37] 张英会等.弹簧手册.机械工业出版社.1997.6:174-246
[38] 张亮李云.流体力学.哈尔滨工程大学出版社.2001.6
[39] 茅春浦.流体力学.上海交通大学出版社.1995.12
[40] 胡敏良.流体力学.武汉工业大学出版社.2000.7.
[41] 蒋新松等.水下机器人.辽宁科学技术出版社2001.11
[42] 邢克飞.Pro/Engineer2001从入门到精通.西安电子科技大学出版社.2002.7
[43] 苏茜 刘莹.实战基础入门Pro/Engineer2001.中国铁道出版社.2002.9
[44] 李军 邢俊文等.ADAMS实例教程.北京理工大学出版社.2002.7
[45] 王国强 张进平等.虚拟样机技术及其在ADAMS上的实践.西北工业大学出版社.2002.3
[46] 郑健荣.ADAMS—虚拟样机技术入门与提高.机械工业出版社.2002.1
[47] George C Williamson, W Mark Bohon.Evaluation of ultrasonic intelligent pig performance:inherent technical problems as a pipeline inspection tool-part 1. CORROSOION PREVENTION&CONTROL. 1994.12:148-152
[48] [日]无损探伤学会编.超声波探伤A.第一版 南京:江苏科学技术出版社.1980
[49] 张玉清等.IBM PC微型计算机原理及接口技术.人民邮电出版社.1997.10
[50] M.Yoshida.K.Endo,N.Masuda, et al.Corrosion Inspection Pig for Gas Pipeline.NKK Technical Report. 1990,(133);43-48
[51] 王玉良等.微机原理与接口技术.北京邮电大学出版社.2001.6