快速吹製成型(QPF)製作５０８３鋁合金手機殼之研究

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：61

、訪客IP：3.144.242.165

姓名

鄭任展(JEN-CHAN CHENG) 查詢紙本館藏

畢業系所

機械工程學系

論文名稱

快速吹製成型(QPF)製作５０８３鋁合金手機殼之研究
(Study on the Production of 5083 Aluminum Alloy Mobile Phone Case by Quick Plastic Forming (QPF))

相關論文

★ 使用實驗計劃法求得印刷電路板微鑽針最佳鑽孔參數	★ 滾針軸承保持架用材料之電鍍氫脆研究
★ 強制氧化及熱機處理對鎂合金AZ91D固相回收製程之研究	★ 滾針軸承保持架圓角修正之有限元素分析
★ 透過乾式蝕刻製作新型鍺全包覆式閘極電晶體元件	★ 窗型球柵陣列構裝翹曲及熱應力分析
★ 冷軋延對ZK60擠製材的拉伸與疲勞性質之影響	★ 熱引伸輔助超塑成形製作機翼整流罩之設計及分析
★ 超塑性鋁合金5083用於機翼前緣整流罩之研究	★ 輕合金輪圈疲勞測試與分析
★ 滾針軸承保持架之有限元分析	★ 鎂合金之晶粒細化與超塑性研究
★ 平板式固態氧化物燃料電池穩態熱應力分析	★ 固態氧化物燃料電池連接板電漿鍍膜特性研究
★ 7XXX系鋁合金添加Sc之顯微組織與機械性質研究	★ 高延性鎂合金之特性及成形性研究

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]

[檢視]

[下載]

本電子論文使用權限為同意立即開放。
已達開放權限電子全文僅授權使用者為學術研究之目的，進行個人非營利性質之檢索、閱讀、列印。
請遵守中華民國著作權法之相關規定，切勿任意重製、散佈、改作、轉貼、播送，以免觸法。

摘要(中)

論文是以快速吹製成型(Quick Plastic Forming, QPF)製作5083鋁合金及超塑性5083鋁合金製作金屬手機外殼進行研究探討，實驗研究討論以最快時間吹製不同厚度AA5083鈑材，並比較AA5083及SPF5083兩種材料的差異，以微觀結構方面來觀察及討論AA5083一般晶粒及SPF5083細晶材料討論原材料及加工後材料的差異性，在以各種不同機械性質及成型的厚薄均勻度、尺寸大小結果來探討及評估最快及最有效率的吹製時間。實驗主要分成三個部分，第一部分是討論AA5083鋁合金0.8mm鈑片、第二部分是討論AA5083鋁合金金屬鈑片0.6mm鈑片、第三部分是討論AA5083及SPF5083鋁合金0.9mm鋁合金金屬鈑片並整合各部分時間對於尺寸與厚薄均勻度的影響。

摘要(英)

The paper is based on Quick Plastic Forming (QPF), which is made of 5083 aluminum alloy and superplastic 5083 aluminum alloy to make metal mobile phone casing. The experimental research discusses the fastest time to blow different thickness AA5083 coffins and compare them. The differences between AA5083 and SPF5083 materials are observed and discussed in terms of microstructure. The differences between AA5083 general grain and SPF5083 fine-grained materials are discussed. The thickness and uniformity of the raw materials and processed materials are discussed in various mechanical properties. Size results to explore and evaluate the fastest and most efficient blowing time. The experiment is mainly divided into three parts, the first part is to discuss AA5083 aluminum alloy 0.8mm material, the second part is to discuss AA5083 aluminum alloy metal material 0.6mm material, the third part is to discuss AA5083 and SPF5083 aluminum alloy 0.9mm aluminum alloy metal material and integrate The effect of each part time on size and thickness uniformity.

關鍵字(中)

★ 快塑成型
★ 5083 鋁合金
★ 金屬手機殼

關鍵字(英)

★ QPF
★ 5083 Aluminum alloy
★ Metal cellphone shell

論文目次

摘要 i
Abstract ii
誌謝 iii
目錄 iv
圖目錄 vii
表目錄 xi
符號說明 xii
第一章緒論 1
1-1前言 1
1-2研究動機與目的 1
第二章文獻探討 3
2-1超塑與快速性成型概論 3
2-1-1 超塑性成型 3
2-1-2 快速性成型 5
2-2 快速與超塑性差異 6
2-2-1 材料差異 7
2-2-2 速率差異[22] 10
2-2-3 溫度差異 12
2-3高溫潤滑 13
第三章實驗方法與步驟 15
3-1實驗材料 15
3-2實驗設備與檢測儀器 16
3-3實驗步驟 22
3-3-1實驗流程 22
3-3-2腐蝕液調配 23
3-3-3金相研磨 24
3-4實驗方法 24
3-4-1硬度實驗 24
3-4-2顯微組織觀察 25
3-4-3快塑成型 26
3-4-4實驗量測 31
3-5實驗結果 34
3-5-1硬度試驗 34
3-5-2微觀結構 37
3-5-3快速成型 42
3-5-4成型厚度分析 45
第四章實驗結果與討論 58
參考文獻 60

參考文獻

[1]F. Yang & W. Yang, “Kinetics and size effect of grain rotations in nanocrystals with rounded triple junctions”, Scripta Materialia, Vol 61, pp.919-922, 2009.
[2]C. M. Hu, C. M. Lai, P. W. Kao, N. J. Ho, J. C. Huang, “Quantitative measurements of small scaled grain sliding in ultra-fine grained Al–Zn alloys produced by friction stir processing”, Materials Characterization, Vol 61, pp.1043-1053, 2010.
[3]Alan I. Taub, Paul E. Krajewski, Alan A. Luo, John N. Owens, "The Evolution of Technology for Materials Processing over the Last 50 Years: The Automotive Example", JOM, Vol 59, 2, pp.48–57, 2007.
[4]L.D. Hefti, “Commercial Airplane Applications of Superplastically Formed AA5083 Aluminum Sheet”, Journal of Materials Engineering and Performance, Vol 16, pp.136-141, 2007.
[5]P. E. Krajewski, J. G. Schroth, “Overview of Quick Plastic Forming Technology”, Materials Science Forum, Vol 551-552, pp.3-12, 2007.
[6]R. Boissiere, S. Terzi, J. J. Blandin, L. Salvo, “Quick-Plastic forming: similarities and differences with Super-Plastic forming”, 6th EUROSPF Conference, pp.1-2, 2009.
[7]J. Carpenter and M. T. Smith, “Quick Plastic Forming of Aluminum Sheet Metal”, Energy Efficiency and Renewable Energy, 2005.
[8]Mary Anne Kulas, Paul E. Krajewski, John R. Bradley, Eric M. Taleff, "Forming Limit Diagrams for AA5083 under SPF and QPF Conditions", Materials Science Forum, Vol 551-552, pp.129-134, 2007
[9]Moinuddin Sirdar Rashid, Chongmin Kim, Edward Frank Ryntz, Frederick Irvin Saunders, Ravi Verma, Sooho Kim, "Quick plastic forming of aluminum alloy sheet metal", U. S. Patent, No. 6253588 B1, 2001.
[10]Richard Murray Kleber, Nelson T. Brinas, Dana W. Moore, Donald L. Kenyon, Joseph B. Harris, "Panel extraction assist for superplastic and quick plastic forming equipment ", U. S. Patent, No. 6615631 B2, 2003.
[11]Arianna T. Morales, "Coating for superplastic and quick plastic forming tool and process of using", U. S. Patent, No. 6655181 B2, 2003.
[12]Chongmin Kim, Gary A. Kruger, "High throughput quick-plastic-forming ", U. S. Patent, No. 7028519 B2, 2006.
[13]Richard H. Hammar, Gary A. Kruger, James G. Schroth, Edward W. 54 Bennett, Curtis L. Shinabarker, "Hot die cleaning system for quick plastic forming cell", U. S. Patent, No. 7204110 B2, 2007.
[14]Sydney Coleman, Bruce Goodreau, "Lubricant for quick plastic forming of aluminum sheet", U. S. Patent, No. 0262120 A1, 2007.
[15]Gary A. Kruger, Chongmin Kim, Richard H. Hammar, "Method for vaccum assisted preforming of superplastically or quick plastically formed article", U. S. Patent, No. 7363790 B2, 2008.
[16]Richard H. Hammar, Richard M. Kleber, Gary A. Kruger, "Open press thermal gap for QPF forming tools", U. S. Patent, No. 7823430 B2, 2010.
[17]Moinuddin S. Rashid, Chongmin Kim, Edward F. Ryntz, Frederick I. Saunders, Ravi Verma, Sooho Kim, Paul E. Krajewski, "Quick plastic forming of aluminum alloy sheet metal", U. S. Patent, No. RE43012 E, 2011.
[18]J.W. Edington K.N. Melton and C.P. Cutler, “Superplasticity” Progress International Materials Science, Vol. 21, No.2, pp.5, (1976)
[19]A. K. Mukherjee and R. S. Mishra, “Superplasticity”, Encyclopedia of Materials: Science and Technology (Second Edition), pp.8977-8981, 2001.
[20]P. E. Krajewski and J. G. Schroth, Superplastic Forming of Advanced Metallic Materials: Methods and Applications, Woodhead Publishing Limited.,2011.
[21]J. R. Bradley, "Bulge testing of superplastic AA5083 aluminum sheet", Advances in Superplasticity and Superplastic Forming by TMS, pp.109–118, Charlotte, NC, 2004.
[22]孫稟厚,「鎂合金 AZ31 細晶薄鈑片拉伸性質與氣壓成型特性研究」,國立中央大學，博士論文，21-23 頁，民國 100 年。
[23]O.D. Sherby and J. Wadsworth: Progr. Mater. Sci., 33, 1989,p.169.
[24]O.D. Sherby, M. Burke, Prog. Mater. Sci., 13, 1966, p.323.
[25]J.W. Edington, K.N. Melton and C.P. Cutler, Prog. Mater. Sci.21, 1976, p. 67.
[26]J.W. Edington, K.N. Melton and C.P. Cutler, “Progress In Mat Sci.”, Vol.21, No2, 1976, p.61.
[27]SJ Hosseinipour, "An investigation into hot deformation of aluminum alloy 5083", Volume 30, Issue 2, February 2009, Pages 319-322.

指導教授

李雄(Shyong Lee)

審核日期

2019-6-18

推文