二元光学激光直写设备传动系统结构设计与分析
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摘要
激光直写是衍射光学元件的一种先进制作技术,激光直写设备是采用激光直写技术制作衍射光学元件并开展其研究的物质基础。本文基于中科院长春光机所研制的四轴激光直写设备开展了对其Y轴传动系统的分析研究,可以为相关高精度传动系统的设计和检测提供重要的依据。
本文以二元光学激光直写设备Y轴功能要求和设计指标为基础,提出了该传动系统的总体结构设计方案,并与其它高精度传动方案进行了比较。该传动系统设计方案可以满足长行程、定位精度为亚微米级精度的传动指标要求。同时,对传动系统各个传动环节也提出了具体的结构设计方案,解释了滚珠丝杠副、空气静压导轨、丝杠导轨连接等多个传动环节结构设计的具体思路。对于开展类似结构设计工作,有实际借鉴意义。
对于所提出的传动系统的具体结构,本文也简单地进行了结构性能指标分析。对于该传动系统的最小位移灵敏度、定位精度的影响因素、系统刚度及固有频率都进行了细致的计算,肯定了所提出的结构设计方案。
精度检测环节对于评价设计的优劣是至关重要的,本文也对该传动系统的精度检测过程作了详尽的陈述。介绍了HP5528A双频激光干涉仪、高精度电感测微仪、标准平晶等检测工作中使用的主要检测仪器。重点阐述了传动系统位移灵敏度、导轨直线度、传动系统定位精度的检测过程和检测结果。并简单地评价了检测结果。
Laser Direct Writing (LDW) is an advanced fabrication technique for diffractive optical elements (DOEs). LDW equipment adopting laser direct writing technique is substance foundation for researching and manufacturing DOEs. Basing on the Four-axis LDW equipment manufactured by Changchun Institute of Optics and Fine Mechanics and Physics, Chinese Academy of Science, the paper analyses Y-axis transmission system of this equipment systematically, it can provide some consult for designing and detecting high-precision transmission system.
Basing on Y-axis' function request and design indexes of binary optical element's laser direct writing equipment, and simply contrasting with other projects of high-precision transmission system design, the paper puts forward the project of total structure design of the transmission system. This project meets the transmission index of long stroke and high positioning accuracy, the positioning accuracy is sub-micron degree. At the same time, the paper puts forward the design projects of each part of the transmission system, explains design thoughts of several parts, such as the ballscrew, aerostatic guide, connection of ballscrew and aerostatic guide. So the paper will be a good reference for developing similar task.
For the transmission system structure, the paper analyzes structure performance figure simply. For the transmission system's the least displacement sensitivity, affection factors of positioning accuracy, system toughness and natural frequency, the paper calculates them carefully. Through a great deal of work as above, we affirm that the project of total structure design is feasible.
Because precision detecting is very important, it can judge whether the design is good or not, the paper describes the detecting process detailedly. Several main detecting instruments which are used in the detecting work are introduced, such as HP5528A dynamic calibration, high-precision inductance scale micrometer and the cubical glass which has been demarcated. For the displacement sensitivity and positioning accuracy of transmission system, guide linearity, the detecting process and detecting result are expatiated. The detecting results are evaluated simply.
本文以二元光学激光直写设备Y轴功能要求和设计指标为基础,提出了该传动系统的总体结构设计方案,并与其它高精度传动方案进行了比较。该传动系统设计方案可以满足长行程、定位精度为亚微米级精度的传动指标要求。同时,对传动系统各个传动环节也提出了具体的结构设计方案,解释了滚珠丝杠副、空气静压导轨、丝杠导轨连接等多个传动环节结构设计的具体思路。对于开展类似结构设计工作,有实际借鉴意义。
对于所提出的传动系统的具体结构,本文也简单地进行了结构性能指标分析。对于该传动系统的最小位移灵敏度、定位精度的影响因素、系统刚度及固有频率都进行了细致的计算,肯定了所提出的结构设计方案。
精度检测环节对于评价设计的优劣是至关重要的,本文也对该传动系统的精度检测过程作了详尽的陈述。介绍了HP5528A双频激光干涉仪、高精度电感测微仪、标准平晶等检测工作中使用的主要检测仪器。重点阐述了传动系统位移灵敏度、导轨直线度、传动系统定位精度的检测过程和检测结果。并简单地评价了检测结果。
Laser Direct Writing (LDW) is an advanced fabrication technique for diffractive optical elements (DOEs). LDW equipment adopting laser direct writing technique is substance foundation for researching and manufacturing DOEs. Basing on the Four-axis LDW equipment manufactured by Changchun Institute of Optics and Fine Mechanics and Physics, Chinese Academy of Science, the paper analyses Y-axis transmission system of this equipment systematically, it can provide some consult for designing and detecting high-precision transmission system.
Basing on Y-axis' function request and design indexes of binary optical element's laser direct writing equipment, and simply contrasting with other projects of high-precision transmission system design, the paper puts forward the project of total structure design of the transmission system. This project meets the transmission index of long stroke and high positioning accuracy, the positioning accuracy is sub-micron degree. At the same time, the paper puts forward the design projects of each part of the transmission system, explains design thoughts of several parts, such as the ballscrew, aerostatic guide, connection of ballscrew and aerostatic guide. So the paper will be a good reference for developing similar task.
For the transmission system structure, the paper analyzes structure performance figure simply. For the transmission system's the least displacement sensitivity, affection factors of positioning accuracy, system toughness and natural frequency, the paper calculates them carefully. Through a great deal of work as above, we affirm that the project of total structure design is feasible.
Because precision detecting is very important, it can judge whether the design is good or not, the paper describes the detecting process detailedly. Several main detecting instruments which are used in the detecting work are introduced, such as HP5528A dynamic calibration, high-precision inductance scale micrometer and the cubical glass which has been demarcated. For the displacement sensitivity and positioning accuracy of transmission system, guide linearity, the detecting process and detecting result are expatiated. The detecting results are evaluated simply.
引文
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[2] A.Kathman, et al. Binary optics New Diffractive Elements For The Designer's Tool Kit.Photonics Spectra, 1992, 26(9):125-132.
[3] J.A.Cox. Overview of diffractive optics at Honeywell. Proc. SPIE,884:127~131(1988).
[4] 张景和,廖江红,刘伟,冯晓国.二元光学元件激光直接写入设备的研制.仪器仪表学报,2001,(2):154~157.
[5] 李凤有.激光直写光刻工艺研究.中国科学院研究生院博士学位论文.2002.
[6] 王红岩.激光直接写入设备运动控制系统分析与设计.中围科学院研究 生院硕士学位论文.1997.
[7] 盖玉先,董申.超精密加工机床的关键部件技术.制造技术与机床,2000,(1):7.
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[9] 张伯霖,夏红梅等.数控机床高速化的研究与应用.中国机械工程.2001,12(10):1132~1137.
[10] 刘建琴,张策,王玉新等.微进给机构综述.机械传动.23(1):47~50.
[11] 吴鹰飞,周兆英.超精密定位工作台.微细加工技术.2002,(2):41~47
[12] Hirosh Mizumoto, Makoto Yabuya, Tatsuhito. An angstrom-positioning system using a twist-roller friction drive. Proc. Eng, 1995, 17(1): 57~62.
[13] 薛实福.精密仪器设计.北京:清华大学出版社,1991.
[14] 王秀梅,凌文玉.压电陶瓷驱动微进给伺服控制系统设计.微计算机信息.1999,15(2):42~43.
[15] 吴小川.激光测量技术在数控机床精度检验中的应用.计量与测试技术.2000,27(4):10.
[16] CHEN J S, DWANG I C. A ballscrew drive mechanism with piezo-electric nut for preload and motion control. International Journal of Machine Tools & Manufacture, 2000, 40: 513.
[17] 田地银,田云.关于滚珠丝杠副的选择.电子工艺技术.1997,18(1):18~25.
[18] 初永坤,李益民,白绥滨.精密滚珠丝杠螺母副预紧的方法.机械工艺师.1996,9:15~16.
[19] [日]十合晋一著,刘湘等译.气体轴承的设计与制造.黑龙江科学技术出版社:1.
[20] 戴一帆,彭小强.超精密车床伺服进给机构设计研究.光学精密工程.2000,8(4):355~359.
[21] J.W.POWELL著,丁维刚等译.空气静压轴承设计.北京:国防工业出版社.1978:89~101.
[22] 李志来.超高刚度自主式空气静压支承发展现状.光机电信息.1998,15(1):9~11.
[23] 李树森,刘暾,张鹏顺.小孔节流方式对气体静压轴承工作刚度影响的分析.润滑与密封.2000,(4):6~7.
[24] N.Tully, Static and Dynamic Performance of an Infinite Stiffness Hydrostatic Thrust Bearing, Trans, ASME. Ser.F.99, 1977, 106.
[25] 彭书志.花岗石在精密和超精密加工中的应用.光学精密工程.1999.
[26] 刘伟.调焦伺服机构的设计.中国科学院研究生院硕士学位论文.2001.
[27] Paros J M, Weisboro L. How to Design Flexure Hinges. Machine Design, 1965,37(27): 151~157.
[28] 吴鹰飞,周兆英.柔性铰链的应用.中国机械工程.2002,13(18):1615~1618.
[29] 李玉和,李庆祥,陈璐云,白立芬.单轴柔性铰链设计方法研究.清华大学学报(自然科学版).2002,42(2):172~174.
[30] 刘伟.单轴柔性铰链转角刚度的计算机辅助计算.光学精密工程.2000,8(2):36~38.
[31] 郑堤,唐可洪.机电一体化设计基础.北京:机械工业出版社.1997.
[32] 韦子枝,韩立强.机械控制工程基础.北京:兵器工业出版社.1993.
[33] 张景和.丝杠扭转刚度与接触刚度的转换.光学精密工程.2000,8(1):60~64.
[34] 吴小川.应用双频激光干涉仪检验数控机床定位精度.机械工艺师.2000(10):45.
[35] 费业泰.误差理论与数据处理.北京:机械工业出版社.1999.
[36] HP5528A Laser Measurement System User's Guide. Hewlett-Packard, Mar. 1988.
[37] 马品仲.HP5528A激光测试仪在几何量计量中的应用.HP5528A激光测试系统用户会议论文.1994:26~37.
[2] A.Kathman, et al. Binary optics New Diffractive Elements For The Designer's Tool Kit.Photonics Spectra, 1992, 26(9):125-132.
[3] J.A.Cox. Overview of diffractive optics at Honeywell. Proc. SPIE,884:127~131(1988).
[4] 张景和,廖江红,刘伟,冯晓国.二元光学元件激光直接写入设备的研制.仪器仪表学报,2001,(2):154~157.
[5] 李凤有.激光直写光刻工艺研究.中国科学院研究生院博士学位论文.2002.
[6] 王红岩.激光直接写入设备运动控制系统分析与设计.中围科学院研究 生院硕士学位论文.1997.
[7] 盖玉先,董申.超精密加工机床的关键部件技术.制造技术与机床,2000,(1):7.
[8] 田军委,王建华等.超精密驱动机构比较[J].西安工业学院学报,2002,22(1):62~66.
[9] 张伯霖,夏红梅等.数控机床高速化的研究与应用.中国机械工程.2001,12(10):1132~1137.
[10] 刘建琴,张策,王玉新等.微进给机构综述.机械传动.23(1):47~50.
[11] 吴鹰飞,周兆英.超精密定位工作台.微细加工技术.2002,(2):41~47
[12] Hirosh Mizumoto, Makoto Yabuya, Tatsuhito. An angstrom-positioning system using a twist-roller friction drive. Proc. Eng, 1995, 17(1): 57~62.
[13] 薛实福.精密仪器设计.北京:清华大学出版社,1991.
[14] 王秀梅,凌文玉.压电陶瓷驱动微进给伺服控制系统设计.微计算机信息.1999,15(2):42~43.
[15] 吴小川.激光测量技术在数控机床精度检验中的应用.计量与测试技术.2000,27(4):10.
[16] CHEN J S, DWANG I C. A ballscrew drive mechanism with piezo-electric nut for preload and motion control. International Journal of Machine Tools & Manufacture, 2000, 40: 513.
[17] 田地银,田云.关于滚珠丝杠副的选择.电子工艺技术.1997,18(1):18~25.
[18] 初永坤,李益民,白绥滨.精密滚珠丝杠螺母副预紧的方法.机械工艺师.1996,9:15~16.
[19] [日]十合晋一著,刘湘等译.气体轴承的设计与制造.黑龙江科学技术出版社:1.
[20] 戴一帆,彭小强.超精密车床伺服进给机构设计研究.光学精密工程.2000,8(4):355~359.
[21] J.W.POWELL著,丁维刚等译.空气静压轴承设计.北京:国防工业出版社.1978:89~101.
[22] 李志来.超高刚度自主式空气静压支承发展现状.光机电信息.1998,15(1):9~11.
[23] 李树森,刘暾,张鹏顺.小孔节流方式对气体静压轴承工作刚度影响的分析.润滑与密封.2000,(4):6~7.
[24] N.Tully, Static and Dynamic Performance of an Infinite Stiffness Hydrostatic Thrust Bearing, Trans, ASME. Ser.F.99, 1977, 106.
[25] 彭书志.花岗石在精密和超精密加工中的应用.光学精密工程.1999.
[26] 刘伟.调焦伺服机构的设计.中国科学院研究生院硕士学位论文.2001.
[27] Paros J M, Weisboro L. How to Design Flexure Hinges. Machine Design, 1965,37(27): 151~157.
[28] 吴鹰飞,周兆英.柔性铰链的应用.中国机械工程.2002,13(18):1615~1618.
[29] 李玉和,李庆祥,陈璐云,白立芬.单轴柔性铰链设计方法研究.清华大学学报(自然科学版).2002,42(2):172~174.
[30] 刘伟.单轴柔性铰链转角刚度的计算机辅助计算.光学精密工程.2000,8(2):36~38.
[31] 郑堤,唐可洪.机电一体化设计基础.北京:机械工业出版社.1997.
[32] 韦子枝,韩立强.机械控制工程基础.北京:兵器工业出版社.1993.
[33] 张景和.丝杠扭转刚度与接触刚度的转换.光学精密工程.2000,8(1):60~64.
[34] 吴小川.应用双频激光干涉仪检验数控机床定位精度.机械工艺师.2000(10):45.
[35] 费业泰.误差理论与数据处理.北京:机械工业出版社.1999.
[36] HP5528A Laser Measurement System User's Guide. Hewlett-Packard, Mar. 1988.
[37] 马品仲.HP5528A激光测试仪在几何量计量中的应用.HP5528A激光测试系统用户会议论文.1994:26~37.