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研究生:滿梓芸
研究生(外文):Tzu-Yun Man
論文名稱:超薄板料連續沖彎成形分析與模具設計
論文名稱(外文):Forming analysis and die design of the progressive shearing-bending processes for the ultra thin sheet metal
指導教授:許源泉許源泉引用關係
學位類別:碩士
校院名稱:國立虎尾科技大學
系所名稱:創意工程與精密科技研究所
學門:藝術學門
學類:視覺藝術學類
論文種類:學術論文
論文出版年:2009
畢業學年度:97
語文別:中文
論文頁數:166
中文關鍵詞:彈片沖剪成形彎曲成形連續沖壓模具
外文關鍵詞:spring chipshearingbendingprogressive stamping die
相關次數:
  • 被引用被引用:15
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本研究結合有限元素模擬軟體與沖模設計理論,探討光碟機固定用彈片之沖壓製程分析與模具設計。在沖剪成形分析上,主要探討模具間隙與壓料壓力對沖剪斷面之影響;在彎曲成形分析上,則是探討模具間隙、壓料壓力以及沖彎速度對於板材成形性之影響,分別透過有限元素分析軟體對沖剪與彎曲行為進行分析,並驗證CAE模擬板材成形之正確性。利用沖模設計理論探討如何設計一套光碟機固定用彈片之沖彎連續模具,首先從產品預評分析、產品加工性分析、板料展開樣式、料條佈置與排列、製程參數計算、模具總體設計、模具零件設計等開發流程,建構出適用於板材沖彎開發與設計系統。
本研究透過板材試驗建構出SUS304板材完整的資料庫。經由研究結果顯示,在板材沖剪方面,當模具間隙越小時,模輥面與撕裂面尺寸值越小,而剪切面尺寸則會越大;當壓料壓力越大時,模輥面與撕裂面尺寸值越小,而剪切面尺寸則會越大。在板材彎曲方面,影響尺寸精度及回彈量之主要參數為模具間隙與壓料壓力;影響板材應變之主要參數為模具間隙與沖彎速度。在模具設計方面,在料條佈置設計上,必須注意到每個道次之間的關聯性與連續性,考慮到帶料、拉料、力量平衡、回彈等問題,以有效地完成3D實體料帶佈置與排列,而在模具總體設計方面,建構出沖模行程、浮料高度、沖頭高度和脫料板行程等資訊,建立出一個實體模具。
將沖彎連續模具進行模具加工與組裝,藉由實際沖彎測試來驗證模擬與設計之可行性,並檢測光碟機固定用彈片之尺寸精度、回彈量以及沖剪斷面情形,經由實驗數據與模擬分析之數據互相比對後,其分析結果顯示 模擬與實際相符合,更加驗證有限元素分析軟體應用於板材沖剪與彎曲成形之可行性與可靠性。
在有限元素模擬軟體及沖模設計軟體的雙管齊下中,不但可以節省模具開發時程和成本,更可以提高成品的尺寸精度,就目前工業的發展來看,對於產品已經有微小化的趨勢,欲達到此目的,利用科學方法,有助於提升模具品質和產品精度。透過本文對於板材沖彎之開發與研究,有助於提供學術界與產業界之參考。
In this current study, finite element method (FEM) software and stamping die design theories were employed to investigate the stamping processes and die design of the immoveable spring chip in CD-ROM.
The shearing and the bending were analyzed by finite element method software and then the accuracy of sheets forming simulated through CAE was tested. In the shearing analysis, focuses were mainly on the effects of clearance and pressure on the shearing surface quality, while in the bending analysis, the effects of die clearance, strip hold pressure, and shearing-bending velocity on sheets forming was explored.
In addition, stamping die design theories were employed to investigate the die design system of sheets metal punching-bending for the immoveable spring chip in CD-ROM. Through the development processes, such as products assessment, stamping analysis, blank development, strip layout, process parameters calculation, die overall designs, and part design of dies, the development and design system for sheets metal punching-bending was constructed.
In this study, a complete database for the SUS304 sheets metal detail properties was also constructed through the tensile test. Results of the study showed that the size values of the rollover plane and the fracture plane decrease as the die clearance decreases, but the burnish plane increases as the die clearance decreases. However, when the strip hold pressure increases, the size values of rollover plane and the fracture plane decrease accordingly, and the size of burnish plane increases as the strip hold pressure increases.
In the aspect of bending analysis, the major parameters affecting the dimensions accuracy and the springback were the die clearance and strip hold pressure, while the die clearance and shearing-bending velocity were the main parameters which influenced the sheets metal strain.
In the design of the strip, attention should be paid to the relations and continuity between the strip designs, such as strip design, strip feeding, force balance, and springback. Then, the overall solid progressive die was constructed after the press stroke, blank lifting height, punch length and stripper travel distances had been determined.
The feasibility of the simulation and the dies deign was confirmed by dies manufacturing, erection and experiment. Furthermore, dimensions accuracy, springback and shearing-bending section of the immoveable spring chip in CD-ROM were examined. The results showed that the numerical values agree with the simulation ones with a reasonable accuracy, which further confirmed the feasibility and reliability of the application of FEM software for the sheets metal shearing-bending process.
Harnessing both FEM and stamping die design software has been proved not only to save the time for, and the cost of, the die development, but also to raise the quality and precision of the products. When the current trend of industrial development is product miniaturization, the exploitation of scientific methods surely will be the core to the satisfaction of the purpose.
The results found in the current study will shed some lights on the research and development of sheets metal shearing-bending process for the academia and industry.
中文摘要.....................................i
ABSTRACT.....................................iii
致謝.........................................v
目錄.........................................vi
表目錄.......................................x
圖目錄.......................................xii
符號說明.....................................xvii
第一章 緒論..................................1
1.1前言......................................1
1.2研究動機與目的............................3
1.3研究方法與步驟............................4
1.4文獻回顧..................................7
1.5論文總覽..................................13
第二章 薄板沖彎與模具設計原理................14
2.1板金成形理論..............................14
2.1.1基本塑性力學............................15
2.1.2材料之降伏準則..........................16
2.1.3材料之延性破裂準則......................19
2.2薄板沖剪原理..............................21
2.2.1板材之沖剪負荷..........................24
2.2.2模具間隙................................25
2.3薄板彎曲原理..............................27
2.3.1板材之彎曲壓力..........................31
2.3.2回彈現象................................32
2.4連續模具設計原理..........................35
2.4.1連續模具之採用與設計原則................38
2.4.2連續模具之基本形式......................41
第三章 研究方法..............................44
3.1薄板機械性質拉伸試驗......................44
3.1.1實驗原理................................44
3.1.2 實驗步驟...............................47
3.2 沖剪製程模擬.............................54
3.2.1 DEFORM軟體之簡介.......................54
3.2.2 沖剪製程模擬規劃.......................57
3.3 彎曲製程模擬.............................59
3.3.1 PAM-STAMP之簡介........................59
3.3.2 彎曲製程模擬規劃.......................61
3.4 製程參數最佳化...........................64
3.4.1 田口原理...............................64
3.4.2 田口方法...............................66
3.5模具設計..................................67
3.5.1 VISI之簡介.............................67
3.5.2 沖彎連續模具設計方法...................68
3.6模具製作與沖彎實驗........................69
3.6.1 模具製作...............................69
3.6.2沖彎實驗................................70
3.6.3沖彎件檢測..............................71
第四章 結果與討論............................73
4.1薄板機械性質分析..........................73
4.2 沖剪成形分析.............................78
4.2.1板材成形剪斷面之分析....................78
4.2.2板材成形應力應變之分析..................85
4.3 彎曲成形分析.............................89
4.3.1板材尺寸精度之分析......................89
4.3.2板材回彈量之分析........................101
4.3.3板材應變之分析..........................113
4.4 模具設計.................................123
4.4.1沖彎件分析..............................123
4.4.2板料展開與料條佈置......................124
4.4.3模具總體設計............................131
4.4.4模具零件設計............................139
4.4.5沖彎測試實驗............................141
4.4.6結果比對與分析..........................146
第五章 結論與建議............................149
5.1結論......................................149
5.2建議......................................152
參考文獻.....................................153
附錄.........................................156
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