三軸數控工具機之即時體積誤差補償系統之研製

Han-Ming Yen; 顏翰銘

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/51778

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	范光照(Kuang-Chao Fan)
dc.contributor.author	Han-Ming Yen	en
dc.contributor.author	顏翰銘	zh_TW
dc.date.accessioned	2021-06-15T13:49:18Z	-
dc.date.available	2015-12-01
dc.date.copyright	2015-12-01
dc.date.issued	2014
dc.date.submitted	2015-10-24
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[7]ISO 230-6: 2002 Test code for machine tools – Part 6: Determination of positioning accuracy on body and face diagonals (Diagonal displacement test), an International Standard, by International Standards Organization, 2002. [8]C. Wang, Laser vector measurement technique for the determination and compensation of volumetric positioning errors. Part 1: Basic theory. Review of scientific instruments, 71(10), p. 3933-3937, 2000. [9]Chinh B.Bui, JoohoHwang, Chan-HongLee, Chun-HongPark, 'Three-face step-diagonal measurement method for the estimation of volumetric positioning errors in a 3Dworkspace', International Journal of Machine Tools & Manufacture, vol60, p.40-43, 2012 73 [10]K.C. Fan, M.J. Chen, W.M. Huang, “A six-degree-of-freedom measurement system for the motion accuracy of linear stages”, International Journal of Machine Tools and Manufacture, 38(3), p.155-164, 1998. [11]C. H. Liu, W. Y. Jywe, C.C. Hsu, and T. H. Hsu, Development of a laser-based high-precision six degree-of-freedom motion errors measurement system for linear stage. Rev. Sci. Instrum., 76(5), p. 1–6, 2005. [12]I. Rahneberg, H.-J. Buchner, G. Jager, Optical system for the simultaneous measurement of two-dimensional straightness errors and the roll angle, Proceedings of SPIE - The International Society for Optical Engineering, 7356, art. no.73560S, 2009. [13]C. Kuang, Q. Feng, B. Zhang, B. Liu, S. Chen, Z. Zhang, A four-degree-of-freedom laser measurement system (FDMS) using a single-mode fiber-coupled laser module, Sensors and Actuators, A: Physical, 125(1), p.100-108, 2005. [14]H.L. Huang, C.H. Liu, W.Y. Jywe, M.S. Wang, Y.R. Jeng, L.L. Duan, and T.H. Hsu, 'Development of a DVD pickup-based four-degrees- of-freedom motion error measuring system for a single-axis linear moving platform,' Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 224(1): p. 37-50, 2009. [15]C.H. Liu, H.L. Huang, and H.W. Lee, 'Five-degrees-of-freedom diffractive laser encoder,' Applied Optics, 48(14): p. 2767-2777, 2009. [16]H.L. Huang, C.H. Liu, W.Y. Jywe, and M.S. Wang, 'High-resolution three-degrees-of-freedom motion errors measuring system for a single-axis linear moving platform,' Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 223(1): p. 107-114, 2009. [17]T-H Wang, “Development of an Abbe error compensator for NC machine tools,” 74Master Thesis, National Taiwan University, 2011. [18]ChaBum Lee, Gyu Ha Kim and Sun-Kyu Lee, “Design and construction of a single unit multi-function optical encoder for a six-degree-of-freedom motion error measurement in an ultraprecision linear stage” , Measurement Science and Technology, 22 (10)：P. 1-8, 2011 [19]Huang, P. and J. Ni, Multi-degree-of-freedom geometric error measurement system. 1995, Google Patents. [20]Kuang, C., E. Hong, and J. Ni, A high-precision five-degree-of-freedom measurement system based on laser collimator and interferometry techniques. Review of Scientific Instruments, 2007, 78 (9) [21]陳亮嘉, “電腦輔助切削中自動量測與補償系統之研製”, 國立台灣大學機械工程研究所碩士論文, 1990. [22]Gangwei Cui, Yong Lu, Jianguang Li, Dong Gao and Yingxue Yao, “Geometric error compensation software system for CNC machine tools based on NC program reconstructing” , Int J Adv Manuf Technol, 2012 [23]M.A. Donmez, D.S. Blomquist, R.J. Hocken, C.R. Liu, and M.M. Barash, “A general methodology for machine tool accuracy enhancement by error compensation”, Precision Engineering, Vol.8, No.4, pp.187-196,1986. [24]FANUC Series 20i-MODEL B, CONNECETION MANUAL(FUNCTION), Volume 3 of 3, pp. 1839-1851. [25]K.C. Fan, “An intelligent thermal error compensation system for CNC machining Center,” J. of Chinese Society of Mechanical Engineers, Vol. 28, No. 1, pp. 81-90, 2007 . [26]Lin, S.Y., “Development and applications of multi-degree-of-freedom angular error measurement system,” Master Thesis, National Taiwan University, 2010 [27]C-H Wang, “Development of an Abbe error compensator for 3-axis NC machine 75tools,” Master Thesis, National Taiwan University, 2012. [28]Huang, Z.N., “The Application of Precision Metrology on Precision Machine,” Master Thesis, National Taiwan University, 2013 [29]http://cn.machinetools.net.tw/machining-center/spec-44-235-420-31-06.htm
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/51778	-
dc.description.abstract	數控工具機的位置回授控制均採用位移感測器(光學尺或編碼器)的單感測系統，但是其位移感測器之量測軸線永遠無法和切削刀具在加工空間的運動軸線同軸，非同軸所產生之誤差為眾所周知之阿貝原理，而各軸移動時具有無法避免之基本六自由度幾何誤差(三線性三角度)，其中偏角誤差更會因阿貝原理而放大，因此阿貝誤差是工具機體積誤差來源中主要成因。本研究中自行研發體積誤差補償系統為多感測回饋補償系統(Multi-sensor feed-back compensation system)，由現有NC控制器之單感測系統與多角度感測器所組成，可即時量測運動平台之偏角誤差與阿貝偏位量，動態補償工具機體積誤差。本系統可建於PC-base控制器內，使得數控工具機具有內藏式體積誤差補償系統功能。量測系統利用實驗室自行開發之自動視準儀與滾動度感測器，組成一套可同時量測三角度(Pitch, Yaw, Roll)之三角度感測器，配合電路板處理將電壓訊號傳輸至PC-based控制器，再配合控制器內根據不同機台之結構配置、位置回授方式，進而推導體積誤差通式，最後進行實驗驗證之。實驗結果可知，以旋轉編碼器做位置回授，其定位誤差主要由阿貝誤差造成，經補償後，其定位精度可有效提升80%以上，工具機精度可大幅改善。	zh_TW
dc.description.abstract	The position feedback control of NC machine tool controllers mostly employs displacement sensor (such as optical scale or encoder) as a single sensor system. Distance between axis of sensor and axis of cutting could lead to massive enlargement of the positioning error of each axis which is known as the Abbe principle. The movement of linear stage inherently has position and orientation errors in six degree of freedom, which are three linear errors (positioning error, horizontal straightness and vertical straightness) and three rotational angles (pitch, yaw and roll). As a result, Abbe error is considered to be the major cause for volumetric error of machine tool. In this study, a multi-sensor feed-back compensation system which consists of three angular sensors and NC controller is developed to greatly enhance the machine tool accuracy by detecting angular errors in real-time and corresponding Abbe offsets so as to compensate for the Abbe errors dynamically. It can also be embedded in NC controllers to improve the accuracy of machine tool. In the measurement system, autocollimator and roll are deployed to monitor the angular errors of machine tool by constantly converting the measuring signals into Pc-based controller(with embedded volumetric error model) Experiments show that the positioning error of an investigated NC machine tool Fis mainly affected by Abbe error. With the proposed volumetric error compensation system, the positioning accuracy can be significantly improved by more than 80%.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T13:49:18Z (GMT). No. of bitstreams: 1 ntu-103-R01522731-1.pdf: 8222436 bytes, checksum: aa0975dc4f27ae80767080c43ece0cdf (MD5) Previous issue date: 2014	en
dc.description.tableofcontents	封面 A 口試委員審定書 B 誌謝 C 摘要 D Abstract E Chapter 1 緒論 1 1-1.研究動機與目的 1 1-2.文獻回顧 5 1-2-1體積誤差推導與檢測 5 1-2-2多自由度量測系統 8 1-2-3補償器設計 14 1-3.研究方法與內容概要 15 Chapter 2三角度感測器 17 2-1.量測原理 17 2-1-1四象限感測器 17 2-1-2自動視準儀原理 19 2-1-3滾動度量測原理 20 2-2.量測系統架構 21 Chapter 3 阿貝誤差補償器設計 24 3-1.系統架構 24 3-2.整合電路板 25 Chapter 4 體積誤差公式推導(奕達機與師大機) 27 4-1.前言 27 4-2.阿貝偏位(師大機) 29 4-3.體積誤差公式(師大機) 33 4-4.體積誤差公式中直線度模型修正(師大機) 34 4-5.阿貝誤差對三軸定位誤差的影響(師大機) 37 4-6.阿貝偏位(奕達機) 38 4-7.體積誤差公式(奕達機) 42 4-8.體積誤差公式中直線度模型修正(奕達機) 43 4-9.阿貝誤差對三軸定位誤差的影響 47 Chapter 5 體積誤差量測與補償 49 5-1.定位誤差驗證(師大機) 49 5-1-1桌上型工具機 X軸 (師大機) 49 5-1-2桌上型工具機 Y軸 (師大機) 53 5-1-3桌上型工具機 Z軸 (師大機) 60 5-2.定位誤差驗證(奕達機) 61 5-2-1大型工具機 X軸 (奕達機) 61 5-2-2大型工具機 Y軸 (奕達機) 66 Chapter 6結論與未來展望 70 6-1.結論 70 6-2.未來展望 71 參考文獻 72
dc.language.iso	zh-TW
dc.title	三軸數控工具機之即時體積誤差補償系統之研製	zh_TW
dc.title	Development of real-time volumetric error compensation system for 3-axis Machine Tools	en
dc.type	Thesis
dc.date.schoolyear	104-1
dc.description.degree	碩士
dc.contributor.oralexamcommittee	修芳仲(Fang-Jung Shiou),陳亮嘉(Chen Liang-Chia)
dc.subject.keyword	數控工具機,阿貝誤差,即時體積誤差補償系統,三角度感測器,	zh_TW
dc.subject.keyword	NC machine tool,Abbe error,real-time volumetric error compensator,three angle sensor,	en
dc.relation.page	75
dc.rights.note	有償授權
dc.date.accepted	2015-10-26
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	機械工程學研究所	zh_TW
顯示於系所單位：	機械工程學系

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