CNC蝸桿磨床程式與人機介面開發

以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：18

、訪客IP：18.226.34.215

姓名

葉國鑫(Ye-Guo-Sin) 查詢紙本館藏

畢業系所

機械工程學系

論文名稱

CNC蝸桿磨床程式與人機介面開發
(Development of CNC Worm Grinding Machine Program and the Human Machine Interface)

相關論文

★ G10液晶玻璃基板之機械手臂牙叉結構改良與最佳化設計	★ 線性齒頂修整對正齒輪之傳動誤差與嚙合頻能量影響分析
★ 沖床齒輪分析與改善	★ 以互補型盤狀圓弧刀具創成之曲線齒齒輪有限元素應力分析
★ 修整型曲線齒輪對齒面接觸應力與負載下傳動誤差之研究	★ 衛載遙測取像儀反射鏡加工缺陷檢測與最佳光學成像品質之運動學裝配設計
★ 應用經驗模態分解法於正齒輪對之傳動誤差分析	★ 小軸交角之修整型正齒輪與凹面錐形齒輪組設計與負載下齒面接觸分析
★ 修整型正齒輪對動態模擬與實驗	★ 應用繞射光學元件之齒輪量測系統開發
★ 漸開線與切線雙圓弧齒形之諧波齒輪有限元素分析與齒形設計	★ 創成螺旋鉋齒刀之砂輪輪廓設計與最佳化
★ 動力刮削創成內正齒輪之刀具齒形輪廓最佳化設計	★ 非接觸式章動減速電機結構設計與模擬
★ Helipoid齒輪接觸特性研究與最佳化分析	★ 高轉速正齒輪之多目標最佳化與動態特性分析

檔案

[Endnote RIS 格式]

[Bibtex 格式]

[相關文章]

[文章引用]

[完整記錄]

[館藏目錄]

至系統瀏覽論文 ( 永不開放)

摘要(中)

本論文依據五型(ZA型、ZN型、ZI型、ZK型以及ZC型)蝸桿之切削方式，基於齒輪原理和微分幾何理論，分別推導出五型蝸桿之齒面數學模式。利用蝸桿之齒面數學模式，配合磨輪之切削機構關係與嚙合方程式，建立五型磨輪之齒面數學模式。根據上述推導之磨輪齒面數學模式，開發了調整磨輪工作區齒形之控制點的功能，並設計修砂盤的路徑規劃以得到更精確的磨輪齒形。

配合廠商機臺的控制器型號與其搭配的程式，撰寫人機介面(Human Machine Interface, HMI)，根據推導之蝸桿與磨輪齒面數學模式，使用C# 程式開發人機介面並用於在CNC蝸桿磨床上。人機介面的功能包括蝸桿基本參數、圓角參數設定、磨輪齒形控制點調整與修砂盤路徑規劃等。為了驗證推導之齒形的正確性，使用合作廠商提供的齒形資料，比對五型修砂盤之修砂路徑的誤差值，最後應用在廠商提供之模擬器上來驗證人機介面程式的可行性。

摘要(英)

Based on the cutting methods, the cylindrical worm is divided into five types, include ZA-type, ZN-type, ZI-type, ZK-type, ZC-type. The mathematical models of the five types worm are derived based on the theory of gearing and differential geometry. The equation of meshing can be obtained by the tooth profile of the worm and the generating grinding wheel. The mathematical models of the five types grinding wheel can be established by applying the cutting mechanism of the grinding wheel process and the equation of meshing. Based on the derived mathematical models of the grinding wheel, adjustment of control points on the tooth profile of the grinding wheel is developed. In addition, the path of the dressing disk is also developed in order to produce the profile of the grinding wheel.

The study is the development of the worm grinding programs from a domestic cooperative manufacturer, the development of the human machine interface (HMI) should be cooperate with the controller model of the manufacturer’s machine and its supporting program. Based on the derived mathematical models of the worm and the grinding wheel, the HMI is developed by using C# codes and applied on the CNC worm grinding machine. The developed functions in the HMI include, basic parameters of worm, round parameter settings, adjustment of control points on the profile of the grinding wheel and path planning of the dressing disk, etc. In order to verify the correctness of the developed tooth profiles, the path of dressing disk is compared to the data of the tooth profile from cooperative manufacturer′s machine. Finally, the HMI will be operated on the simulator to verify the developed codes.

關鍵字(中)

★ 圓柱型蝸桿與磨輪
★ 修砂盤路徑
★ 人機介面
★ CNC蝸桿磨床

關鍵字(英)

★ Cylindrical worm and grinding wheel
★ Dressing disk
★ Human machine interface
★ CNC worm grinding machine

論文目次

摘要 i
Abstract ii
致謝 iii
目錄 iv
圖目錄 vi
表目錄 ix
符號對照表 x
第1章緒論 1
1.1 前言 1
1.2 文獻回顧 1
1.2.1 圓柱型蝸桿蝸輪組介紹與分類 1
1.2.2 B-spline曲線相關應用之文獻回顧 3
1.2.3 人機介面應用之文獻回顧 4
1.3 研究目的 6
1.4 論文架構 7
第2章蝸桿之齒面數學模式 8
2.1 前言 8
2.2 ZA型蝸桿 8
2.2.1 切削ZA型蝸桿之刀具數學模式 8
2.2.2 ZA型蝸桿之齒面數學模式 9
2.3 ZN型蝸桿 12
2.3.1 切削ZN型蝸桿之刀具數學模式 12
2.3.2 ZN型蝸桿之齒面數學模式 15
2.4 ZI型蝸桿 17
2.4.1 ZI型蝸桿之齒面數學模式 17
2.5 ZK型蝸桿 22
2.5.1 切削ZK型蝸桿之刀具數學模式 22
2.5.2 ZK型蝸桿之齒面數學模式 25
2.6 ZC型蝸桿 28
2.6.1 切削ZC型蝸桿之刀具數學模式 28
2.6.2 ZC型蝸桿之齒面數學模式 31
2.7 數值範例 33
2.7.1 五型蝸桿齒形數值範例 33
2.7.2 ZA型多牙口蝸桿 36
2.7.3 ZA型雙導程蝸桿 38
第3章磨輪數學模式 40
3.1 前言 40
3.2 ZA型磨輪數學模式 40
3.3 ZN型磨輪數學模式 44
3.4 ZI型磨輪數學模式 47
3.5 ZK型磨輪數學模式 50
3.6 ZC型磨輪數學模式 50
3.7 數值範例 51
3.7.1 齒頂與齒底圓角區之數學模式 51
3.7.2 五型磨輪齒形數值範例 53
第4章磨輪擬合與修砂路徑規劃 54
4.1 前言 54
4.2 擬合與B-SPLINE曲線方程式 54
4.3 磨輪修砂路徑規劃 56
第5章人機介面設計 59
5.1 前言 59
5.2 人機介面版面與功能介紹 61
5.3 齒形驗證與分析 68
第6章結論與未來工作 82
6.1 結論 82
6.2 未來工作 83
參考文獻 84

參考文獻

[1] ANSI/AGMA 6022-C93, “Design Manual for Cylindrical Wormgearing,” American Gear Manufacturers Association, 2014.
[2] F. L. Litvin and A. Fuentes, “Gear Geometry and Applied Theory,” Cambridge University Press, 2nd edition, New York, 2004.
[3] H. S. Fang and C. B. Tsay, “Mathematical Model and Bearing Contacts of the ZN-Type Worm Gear Set Cut by Oversize Hob Cutters,” Mechanism and Machine Theory, vol. 35, pp. 1689-1708, 2000.
[4] 陳宗賢，非對稱齒形之蝸桿蝸輪組之特性分析，國立交通大學機械工程研究所，碩士論文，民國九十六年。
[5] H. S. Fang, C. B. Tsay and J. W. Jeng , “A Mathematical Model of the ZE-type Worm Gear Set,” Mechanism and Machine Theory, vol. 30, no. 6, pp. 777-7789, 1995.
[6] L. Dong, P. Liu, W. Wei, X. Dong and H. Li, “Study on ZI worm and helical gear drive with large transmission ratio,” Mechanism and Machine Theory, vol. 74, pp. 299-309, 2014.
[7] S. Hamada, K. Kawsaki and I. Tsuji, “Tooth contact analysis and manufacturing of dual lead worm gears in ISO type I,” Journal of Advanced Mechanical Design, Systems, and Manufacturing, vol. 12, no. 1, pp. 17-515, 2018.
[8] H. S. Fang and C. B. Tsay, “Mathematical model and Bearing Contacts of the ZK- Type Worm Gear Set Cut by Oversize Hob Cutters,” Mechanism and Machine Theory, vol. 31, no. 3, pp. 271-282, 1996.
[9] B. W. Bair and C. B. Tsay, “ZK-Type Dual-Lead Worm and Worm Gear Drives: Geometry,” ASME, Journal of Mechanical Design, vol. 120, pp. 414-421, 1998.
[10] Q. X. Meng, Y. P. Zhao, J. Cui and Z. Y. Yang, “Meshing Theory of Mismatched ZC1 Worm Drive,” Mechanism and Machine Theory, vol. 150, p. 103869, 2020.
[11] M. G. Cox, “The numerical evaluation of B-spline,” IMA Journal of Applied Mathematics, vol. 10, pp. 134-149, 1972.
[12] M. G. Cox, “An Alagorithm for spline interpolation,” IMA Journal of Applied Mathematics, vol. 15, pp. 95-108, 1975.
[13] M. G. Cox, “The numerical evaluation of a spline from its B-spline representation,” IMA Journal of Applied Mathematics, vol. 21, pp. 135-143, 1978.
[14] C. D. Boor, “On calculating with B-splines,” Journal of Approximation Theory, vol. 6, pp. 50-62, 1972.
[15] E. Guo, R. Hong, X. Huang, and C. Fang, “A correction method for power skiving of cylindrical gears lead modification,” Journal of Mechanical Science and Technology, vol. 29, no. 10, pp. 4379-4386, 2015.
[16] P. Wang, J. Li, and Y.-Q. Jin, “A study on the design of slicing cutter for cycloid gear based on conjugate theory,” The International Journal of Advanced Manufacturing Technology, vol. 98, no. 5, pp. 2057-2068, 2018.
[17] 王邦宇，五軸CNC成形砂輪磨齒機之人機介面研究，國立臺灣科技大學機械工程研究所，碩士論文，民國一百年。
[18] 謝福霖，虛擬桌上型五軸銑削加工機之3D人機介面開發，國立高雄應用科技大學機械與精密工程研究所，碩士論文，民國一百零一年。
[19] 詹世朗，智慧型NC工具機人機介面系統設計，國立高雄應用科技大學模具工程研究所，碩士論文，民國九十四年。
[20] J.S. Kong, K. Maute, D.M. Frangopol, L. A. Liew, R.A. Saravanan and R. Raj, “A real time human–machine interface for an ultrahigh temperature MEMS sensor–igniter”, Sensors and Actuators A, vol.105, pp.23-30, 2003.
[21] T. G. Lim, C. W. Reeu, “Development of Human- Machine Interface for Automatic Control of Electro-Slag Remelting Process”, Institute of Electrical and Electronics Engineers, pp.501-507, vol.1, 2002.
[22] S. Hori, Y. Shimizu, “Designing methods of human interface for supervisory control systems”, Control Engineering Practice, vol.7, pp.1413-1419, 1999.

指導教授

陳怡呈(Chen, Yi-Cheng)

審核日期

2023-2-1

推文