線切割放電加工機鼓形量之探討與抑制

Che-Wei Liao; 廖哲暐

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/47062

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	廖運炫
dc.contributor.author	Che-Wei Liao	en
dc.contributor.author	廖哲暐	zh_TW
dc.date.accessioned	2021-06-15T05:46:33Z	-
dc.date.available	2012-08-20
dc.date.copyright	2010-08-20
dc.date.issued	2010
dc.date.submitted	2010-08-18
dc.identifier.citation	1. Dauw, D. F., Sthioul, H. and Tricarico, C., “Wire analysis and control for precision EDM cutting,” Annals of CIRP, Vol. 38/1/1989, pp. 191-194. 2. Guo, Z. N., Lee, T. C., Yue, T. M. and Lau W. S., “A study of ultrasonic-aided wire electrical discharge machining,” Journal of Materials Processing Technology, Vol. 63, 1997, pp. 823-828. 3. Arunachalam, C., Aulia, M., Bozkurt, B. and Eubank, P. T., “Wire vibration, bowing, and breakage in wire electrical discharge machining,” Journal of Applied Physics, Vol. 89, No. 8, 15 April 2001, pp. 4255-4262. 4. Han, F., Kunieda, M., Sendai, T. and Imai, Y., “High precision simulation of WEDM using parametric programming,” Annals of CIRP, Vol. 51, 2002, pp. 165-168. 5. Han, F., Kunieda, M., Sendai, T. and Imai, Y., “Simulation on Influence of Electrostatic Force on Machining Characteristics in WEDM,” International Jornal of Electrical Machining, No. 7, 2002, pp. 31-36. 6. Puri, A. B. and Bhattacharyya, B., “Modelling and analysis of the wire-tool vibration in wire-cut EDM,” Journal of Materials Processing Technology, Vol. 141, No. 3, 1 November 2003, pp. 295-301. 7. Masuzawa, T. and Wada, T., “A double wire system for accuracy improvement in WEDM,” Proc. OF the 11th Int. Symposium for ElectroMachining (ISEM-11), Switzerland, 1995, pp. 201-208. 8. Okada, A., Uno, Y., Onoda, S. and Habib, S., “Computational fluid dynamics analysis of working fluid flow and debris movement in wire EDMed kerf,” Annals of CIRP, Vol. 58, 2009, pp. 209-212. 9. 蘇信政，線切割放電加工粗加工鼓形量改善之研究，博士論文，台灣大學機械工程學研究所，中華民國九十八年七月。 10. 許文政，線切割放電加工轉角精度控制策略之研究，博士論文，台灣大學機械工程學研究所，中華民國八十七年六月。 11. 洪銘聰，線切割式放電加工(WEDM)放電點分佈之研究，碩士論文，台灣大學機械工程學研究所，中華民國九十年六月。 12. 董珮君，線切割放電加工機之即時監測系統開發，碩士論文，台灣大學機械工程學研究所，中華民國九十五年七月。 13. 齋藤長男著、賴耿暘譯，放電加工機活用，復漢出版社，中華民國七十年。 14. 伍國瑋，線切割放電加工機放電延遲時間之序列分析，碩士論文，台灣大學機械工程學研究所，中華民國九十八年七月。 15. 陳建宙，能量參數對線切割式放電加工的影響，碩士論文，台灣大學機械工程學研究所，中華民國八十七年七月。 16. 余永平，線切割放電加工材料之能量性質及其應用，博士論文，台灣大學機械工程學研究所，中華民國九十年六月。 17. 邱雲堯，線切割放電加工(WEDM)斷線過程及偵測之研究，碩士論文，台灣大學機械工程學研究所，中華民國八十二年六月。 18. 吳一農，單晶片8051實務，松崗電腦圖書資料股份有限公司，中華民國九十一年。 19. 吳明哲、黃世陽、林義證、蔡文龍，最新C&C++學習範本第二版，松崗電腦圖書資料股份有限公司，中華民國九十四年。
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/47062	-
dc.description.abstract	線切割放電加工程序由於使用銅線為電極，因此或多或少都會在工件側腹上會留下鼓形量的幾何誤差，造成厚度方向不垂直，影響尺寸精度，實務上係以多道次精修的方式解決此問題，但時間及成本上並不經濟。過往研究認為鼓形量成因有二，其一為線極振動造成工件中央易發生放電，其二為工件中央排渣困難，加工絕緣液比電阻值下降，造成二次放電。本研究之在探討影響鼓形量之主要以何者為重，並藉此找出抑制策略。本研究首先針對厚度60mm之SKD11，從線張力和伺服電壓的改變觀察鼓形量之變化，並和放電延遲時間進行關連以找出合適控制指標進行控制策略。實驗結果顯示，隨著張力的上升，線振因素所佔的重要性會下降，抑制線振後排渣的模式將是影響鼓形成因的主因。本研究並發現鼓形量的形態另有二種模式(近直線、不規則)，針對其它兩種鼓形是由於渣流動和間隙大小不同，造成放電點集中程度不同，放電集中程度不同所對應正常放電比也不同。適當的正常放電比會應對有良好的鼓形量。綜合上述發現，本研究提出了一套簡單的控制策略，在伺服進給(G95)的工作條件下，加工時之正常放電比作調整放電休止時間的依據。經實驗證實，正常放電比參考值0.40是一理想參考在本研究的條件之下，針對厚度60mm能將一般伺服進給鼓形量6μm改善到鼓形現象消失，厚度80mm從11μm下降至2μm。	zh_TW
dc.description.abstract	WEDM is a machining process using thin wire electrodes. Because of the flexibility of the wire electrodes, there would be vertical alignment geometric error left on the machined surface. In most workshop practice, the error is corrected through multiple surface-finishing process, which is not efficient in time and cost.The previous studies over this issue proposed that the vertical alignment geometric error were out of two mechanisms – either vibration of the wire electrodes, or the ineffective of debris removal – both making the uneven distribution of the electoral discharge alone the wire electrodes. In this research, with SKD11 alloy of 60mm in thickness as the workpiece, the influences of the wire electrode tension, the servo voltage, and ignition delay time (Td) over the vertical alignment geometric error were observed, and also in conjunction with the ignition delay time of electrical discharged (Td) in order to figure out the suitable control index for feedback automatic control. It showed that, as the wire electrode tension increased, the influence of the wire vibration diminished, which suppressed the removal of the debris making the uneven distribution of electrical discharges. This research also noted that the vertical alignment geometric error could be categorized into two major types: nearly linear type, and irregular type. Different types of the error were attributed to two factors – the flow of debris removal, and the width of discharged gap – which reflected to different normal discharge ratios. Under the adequate normal discharge ratio, the vertical alignment geometric error would be much reduced. Based on the finding stated above, a clean-cut feedback control strategy was proposed in this research. Under the machining setting of servo feeding (G95), the normal discharge ratio was used as the control index to change the discharge off-time for the feedback control. Through on-site experiments, it was proved that, under the machining condition setting of this research, the vertical alignment geometric error could be much decreased with the normal discharge ratio of 40%. For workpiece of 60mm in thickness, the geometric error decreased from 6μm to nearly zero. For workpiece of 80mm in thickness, the geometric error decreased from 11μm to 2μm.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T05:46:33Z (GMT). No. of bitstreams: 1 ntu-99-R97522821-1.pdf: 1725492 bytes, checksum: 9be14f3c0c38e63fc8697c667ab42c3d (MD5) Previous issue date: 2010	en
dc.description.tableofcontents	誌謝................................................................................................................................I 摘要...............................................................................................................................II 英文摘要......................................................................................................................III 目錄...............................................................................................................................V 圖目錄........................................................................................................................VII 表目錄........................................................................................................................IX符號說明......................................................................................................................X 第一章緒論 1 1.1引言 1 1.2 文獻回顧 3 1.3 研究目的與研究方法 7 1.4 本文結構 9 第二章放電加工原理介紹 10 2.1 放電現象簡述與材料移除機制 10 2.2 放電電弧的發展過程 12 2.3 放電火花結構 13 2.4 放電迴路的種類 15 2.5 放電參數與放電波形 17 2.6 放電加工機進給控制系統 20 第三章實驗設備與實驗設計 22 3.1 實驗設備與材料 23 3.2 放電訊號之擷取與處理 30 3.3 正常放電系統的驗證 35 3.4 線上網路傳輸系統 37 第四章實驗結果與討論 39 4.1 伺服電壓、張力和鼓形量之關係 39 4.2 三種鼓形形狀探討 42 4.3 Td對鼓形量的影響 47 4.4 控制器架構 54 4.5 控制結論和實驗 58 第五章結論與建議 63 5.1 鼓形量抑制之研究結論 63 5.2 未來展望 64 參考文獻 65
dc.language.iso	zh-TW
dc.subject	回授控制	zh_TW
dc.subject	線切割放電加工	zh_TW
dc.subject	加工精度	zh_TW
dc.subject	正常放電比	zh_TW
dc.subject	鼓形量	zh_TW
dc.subject	WEDM	en
dc.subject	straightness accuracy	en
dc.subject	normal discharge ratio	en
dc.subject	feedback control	en
dc.subject	drum shape error	en
dc.title	線切割放電加工機鼓形量之探討與抑制	zh_TW
dc.title	A Study on Drum Shape Error in WEDM and the Improvement Strategy	en
dc.type	Thesis
dc.date.schoolyear	98-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	顏木田,許文政
dc.subject.keyword	線切割放電加工,鼓形量,加工精度,正常放電比,回授控制,	zh_TW
dc.subject.keyword	WEDM,drum shape error,straightness accuracy,normal discharge ratio,feedback control,	en
dc.relation.page	68
dc.rights.note	有償授權
dc.date.accepted	2010-08-19
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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