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研究生:陳世昌
研究生(外文):Shi-Cheng Chen
論文名稱:對工具鋼放電加工面之改善效果
論文名稱(外文):The improved effect of EDMed surface roughness on SKD61
指導教授:顏炳華顏炳華引用關係
指導教授(外文):Biing-Hwa Yan
學位類別:碩士
校院名稱:國立中央大學
系所名稱:機械工程研究所
學門:工程學門
學類:機械工程學類
論文種類:學術論文
論文出版年:2003
畢業學年度:91
語文別:中文
論文頁數:94
中文關鍵詞:放電加工界面活性劑鋁粉粉末表面粗糙度
外文關鍵詞:electrical-discharge machining (EDM)surface roughnesssurfactantAl powder
相關次數:
  • 被引用被引用:19
  • 點閱點閱:188
  • 評分評分:
  • 下載下載:0
  • 收藏至我的研究室書目清單書目收藏:1
許多研究顯示,放電加工中添加鋁粉可以產生放電分散的效果,得到較佳的表面粗糙度,雖然鋁粉可以均勻分佈在放電加工液中,因鋁粉粒徑小而產生靜電力,導致鋁粉粉末容易聚集且不易分散於加工液。有鑑於此,本論文之研究目的主要是在探討放電加工液中添加鋁(Al)粉與界面活性劑(surfactant)對改善工具鋼放電加工面的效果,希望能藉由界面活性劑的分散效果,將鋁粉更為均勻地分散於放電加工液中,以達到最佳的表面品質,甚至能夠達到最理想的鏡面效果。
經由田口實驗設計分析顯示,放電加工液中添加鋁粉重量濃度為0.1g/L及界面活性劑重量濃度為0.25g/L,可以達到最佳的分散效果,藉由界面活性劑中的界面活性分子確實能將鋁粉更為均勻地分散於放電加工液中而改善加工特性。當使用正極性加工、電流0.3A、脈衝時間1.5μs、開路電壓140V、極間電壓90V及界面活性劑重量濃度為0.25g/L時,可以得到最佳的表面粗糙度(Ra 0.172μm)。並針對極性、電流、脈衝時間等不同放電參數來進行探討,並經由驗證放電加工液中添加鋁粉與界面活性劑之後,發現純放電液放電後的工件表面的表面粗糙度(Ra)為0.434μm,放電液中添加鋁粉及分散劑的放電表面粗糙度(Ra)可達0.172μm,改善率高達60%。
A lot of research have been exhibited, it can be seen that added Al powder in working fluid will reduce the isolation by its conductive powder and increase the gap distance between the electrode and workpiece to stabilize the process and generate discharging dispersion to improve surface roughness. Smaller size particle will have bring static electricity force and result in powder congregated. In this paper, some results on surface machining by EDM are treated in which several kinds of working fluid. The major research of this study investigates the effect on EDM characteristics by adding aluminum powder and surfactant into working fluid. Hoping to aluminum powder could disperse well mixed and pellet by pellet rely on scatter capability of surfactant is which obtained good quality surface and roughness by EDM.
From the Taguchi method and experiment results, it can be seen that the surfactant could separate Al powder in the working fluid. Therefore, the parameters of polarity, peak current, and pulse duration discussed that added Al powder and surfactant in working fluid will reduce the surface roughness more than only added Al powder in working fluid. In this study, the parameters are positive polarity、peak current 0.3A、pulse duration 1.5μm in the working fluid of Al powder concentration 0.1g/L and surfactant concentration 0.25g/L. Surface roughness could achieve Ra 0.172μm. The surfactant in working fluid of Al powder is able to improve still more surface roughness.
總目錄
謝誌I
摘要II
總目錄IV
圖目錄VII
表目錄IX
第一章 緒論1
1-1放電加工簡史及其發展1
1-2研究背景3
1-3研究動機與目的5
1-4研究方法...7
第二章 放電加工基本原理8
2-1放電加工之基本原理8
2-2放電加工之材料去除機構10
2-3放電加工參數設定及其影響13
2-4放電加工之特性18
2-5放電加工之優缺點21
第三章 界面活性劑之原理與應用22
3-1界面活性劑之基本原理22
3-2界面活性劑之定義24
3-3界面活性劑於本實驗之應用25
第四章 田口品質工程法26
4-1田口法簡介26
4-2實驗設計法28
4-3直交陣列表29
4-4訊號/噪音比31
4-5變異數分析32
4-6驗證實驗34
第五章 實驗設備及方法35
5-1實驗設備35
5-2實驗材料40
5-3實驗材料準備45
5-4實驗加工參數46
5-5實驗設計47
5-6實驗流程圖52
第六章 結果與討論53
6-1放電加工液中添加鋁粉與分散劑的特性53
6-2田口法分析結果與最佳化60
6-2.1表面粗糙度60
6-2.2材料移除率65
6-2.3驗證實驗69
6-3放電特性探討71
6-3.1不同放電加工液對放電特性的影響71
6-3.2極間間隙討論74
6-3.3放電參數對放電加工液之探討76
6-4 表面特性探討87
6-4.1再鑄層觀察與討論87
第七章 結論89
參考文獻91
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