本論文係對五元(TiVCrZrTa)N高性能氮化物鍍膜銑刀，進行切削持性系統的研究，針對在薄膜製備中使用射頻磁控濺鍍系統( RF Magnetron Sputtering System) 製鍍(TiVCrZrTa)N薄膜。
本研究分別使用未鍍膜碳化鎢銑刀與(TiVCrZrTa)N鍍膜銑刀進行304不銹鋼切削優劣比對，並且在切削過程中利用動力計及訊號擷取器收集切削力數據，爾後進行數據研究及分析評估，以及切削後使用SEM觀察結構表面之磨耗。
切削力數據收集評估後，(TiVCrZrTa)N高性能氮化物鍍膜銑刀，顯示出較碳化鎢銑刀更好的金屬切削性能。(TiVCrZrTa)N高性能氮化物鍍膜銑刀的優越性能，在高速下更為顯著。也更加確立(TiVCrZrTa)N鍍膜銑刀對於加工材料與其刃口本身磨損較高抗性具有相關性。這些特徵是在加工操作期間使用(TiVCrZrTa)N鍍膜在刀刃處具有較高的抗磨損、耐高溫以及抗腐蝕特性的結果。

In this paper, we study the preparation of TiVCrZrTa (N) high-performance nitride coating cutter research on cutting and holding systemfilmFor the preparation of thin film using magnetron sputtering system RF (Magnetron Sputtering System) plating (TiVCrZrTa) N film.
In this study, the use of uncoated tungsten carbide milling cutter and (TiVCrZrTa) N coated milling cutter for 304 stainless steel cutting the advantages and disadvantages, and in the cutting process using the power meter and signal extractor to collect cutting force data, and then data research and analysis The abrasion of the structural surface was observed using an SEM after cutting, and after cutting.
After the cutting force data was collected, the (TiVCrZrTa) N high performance nitride coated milling cutter showed better metal cutting performance than the tungsten carbide cutter. (TiVCrZrTa) N high-performance nitride coating milling cutter superior performance, more significant at high speed. Also more established (TiVCrZrTa) N coated milling cutter for the processing of materials and its edge itself is more resistant to wear resistance. These features are the result of the use of (TiVCrZrTa) N coating at the blade edge during processing operations with high wear resistance, high temperature resistance and corrosion resistance.

中文摘要 I
英文摘要 II
誌謝　 IV
目錄　 V
圖目錄　 VII
表目錄　 IX
第一章 緒論 1
1.1 前言 1
1.2 研究目地 2
1.3 論文架構 4
第二章 文獻回顧 5
2.1切削力文獻回顧 5
2.2乾式切削文獻回顧 7
2.3刀具磨耗文獻回顧 8
2.4金屬切削原理 9
2.5切削基礎 10
2.6切削模式 12
2.7切削力學 12
2.8端銑刀原理 14
第三章 設備配置與實驗規劃 17
3.1 實驗流程與參數規劃 17
3.2.1 製鍍(TIVCRZRTA)N薄膜參數 18
3.2.2 切削實驗參數 19
3.2.3 磨耗試驗參數 20
3.3 切削力實驗系統架設與設備 21
3.3.1立式加工中心機 23
3.3.2數據截取系統 24
3.3.3掃描式電子顯微鏡 25
3.3.4工具顯微測量儀 26
3.3.5磨耗試驗機 26
3.4 刀具選用 27
3.5 加工工件 28
3.6 切削實驗步驟 29
第四章 結果與討論 30
4.1轉速铣削實驗分析 30
4.1.1未鍍膜碳化鎢銑刀不同轉速實驗 30
4.1.2(TIVCRZRTA)N鍍膜銑刀不同轉速實驗 32
4.1.3(TIVCRZRTA)N鍍膜銑刀與未鍍膜碳化鎢銑刀平均切削力比較 34
4.1.4(TIVCRZRTA)N鍍膜銑刀與未鍍膜碳化鎢銑刀SEM削屑圖比較 35
4.2深度銑削試驗分析 39
4.2.1(TIVCRZRTA)N鍍膜銑刀與未鍍膜碳化鎢銑刀铣削 39
4.2.2(TIVCRZRTA)N鍍膜銑刀、SKH9與SKH9-CO8未鍍膜銑刀铣削 40
4.3 進給銑削試驗分析 46
4.3.1(TIVCRZRTA)N鍍膜銑刀與未鍍膜碳化鎢銑刀铣削 46
4.3.2(TIVCRZRTA)N鍍膜銑刀、SKH9與SKH9-CO8未鍍膜銑刀铣削 47
4.4 磨耗試驗分析 53
4.4.1(TIVCRZRTA)N多層膜試片SEM表面微結構觀察 53
4.4.2磨耗試驗 55
第五章 結論 58
參考文獻 60

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