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研究生: 陳永斌
Yong-Bin Chen
論文名稱: 微量Sc、Zr對Al-4.6Cu-0.3Mg-0.6Ag合金微結構與機械性質之影響
Effect of Minor Sc and Zr on the Microstructure and Mechanical Properties of Al-4.6Cu-0.3Mg-0.6Ag Alloys
指導教授: 李勝隆
Sheng-Long Lee
口試委員:
學位類別: 碩士
Master
系所名稱: 工學院 - 機械工程學系
Department of Mechanical Engineering
畢業學年度: 92
語文別: 中文
論文頁數: 44
中文關鍵詞: Al-Cu-Mg-Ag合金ScW相
外文關鍵詞: W phase, Al-Cu-Mg-Ag alloys, Sc
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    • Al-Cu-Mg-Ag合金為一高強度鋁合金,藉由Ω相及θ’的析出而達到析出強化的效果。在純鋁或鋁合金中添加Sc元素,可使合金之晶粒細化;且有效提升合金之再結晶溫度,抑制合金發生再結晶;經高溫時效處理後,亦有Al3Sc析出相形成,可提升合金強度。在合金中同時添加Sc及Zr,可減少Sc使用量,亦可得到良好的改良效果。
    本實驗於Al-4.6Cu-0.3Mg-0.6Ag合金中分別添加0.6Sc及0.35Sc +0.07Zr,施以T7時效熱處理,探討Sc、Zr元素對合金微結構與機械性質之影響。利用光學顯微鏡(OM)、掃描式電子顯微鏡(SEM)、穿透式電子顯微鏡(TEM)、微差掃描熱分析儀(DSC)、導電度(%IACS)、硬度試驗、拉伸試驗(Tensile Test)等方法,探討微結構的變化與材料機械性質之關係。
    結果顯示,合金中添加0.6Sc或0.35Sc +0.07Zr時,因Al3Sc及Al3(ScxZr1-x)晶出相的形成,使晶粒明顯細化。此外含Sc的合金於鑄態時即有W(Al8.5-4Cu6.6-4Sc)相形成,且無法經由固溶處理回溶於基地內,因而降低基地內Cu元素固溶量,使得T7熱處理後Ω及θ’ 相析出量降低,造成合金硬度及強度降低,但延性提升。合金中並未發現Al3Sc析出相的形成。

    總目錄 謝誌………………………………………………………………………I 摘要……………………………………………………………………II 總目錄…………………………………………………………………III 圖目錄…………………………………………………………………V 表目錄…………………………………………………………………VII 壹、前言…………………………………………………………………1 1. Al-Cu-Mg-Ag合金簡介………………………………………1 2. Al-Cu-Mg-Ag合金之析出強化相……………………………2 3. Cu/Mg比對Al-Cu-Mg-Ag合金析出之影響………………….4 4. 鋁合金添加Sc元素之文獻回顧………………………………4 5. Al-Cu合金中添加Sc之影響…………………………………8 6. 實驗目的及合金設計………………………………………11 貳、實驗步驟與方法…………………………………………………13 一、合金配製、加工及熱處理…………………………………14 1. 合金配製與成分分析…………………………………14 2. 熱處理…………………………………………………14 二、微結構分析…………………………………………………15 1. OM金相觀察……………………………………………15 2. 導電度(%IACS)量測……………………………………15 3. 微差掃瞄熱分析儀(DSC) ………………………………15 4. 掃瞄式電子顯微鏡(SEM) ……………………………16 5. 電子微探儀(EPMA) ……………………………………16 6. 穿透式電子顯微鏡(TEM) ……………………………16 三、機械性質分析………………………………………………16 1. 硬度試驗………………………………………………17 2. 拉伸試驗………………………………………………17 參、結果與討論………………………………………………………18 1. 微結構分析……………………………………………………18 1.1 金相觀察、能量散佈光譜儀(EDS)及 電子微探儀(EPMA)分析………………………………18 1.2 微差掃瞄熱分析(DSC)及穿透式電子顯微鏡(TEM) 之觀察分析……………………………………………25 1.3 導電度(%IACS)分析……………………………………30 2. 機械性質分析…………………………………………………33 2.1 硬度試驗及拉伸試驗…………………………………33 肆、結論………………………………………………………………38 伍、未來研究方向……………………………………………………39 陸、參考資料…………………………………………………………40 圖目錄 圖1.1 Cu3Au的單位晶格結構示意圖…………………………………5 圖1.2 Al-Sc部分二元相圖………………………………………………5 圖1.3 Al3Zr的L12結構示意圖…………………………………………6 圖1.4 慢速冷卻下Al3Sc晶粒的表面形態……………………………7 圖1.5 Al3Sc的發展示意圖………………………………………………7 圖1.6 快速冷卻(~100 K s-1)下Al3Sc顆粒的表面形態………………7 圖1.7 快速冷卻下Al3Sc顆粒細胞突狀(cellular-dendrite) 結構概要圖………………………………………………………8 圖1.8 鋁-過渡元素再結晶溫度對過渡元素含量比較圖……………9 圖1.9 各合金中添加Sc提升降伏強度之關係圖………………………9 圖1.10 Al-Cu-Sc三元相圖……………………………………………11 圖2.1 實驗流程圖……………………………………………………13 圖2.2 板狀拉伸試片規格……………………………………………17 圖3.1 不同Sc及Zr含量之Al-Cu-Mg-Ag合金於鑄態之 金相圖及晶粒結構……………………………………………19 圖3.2 合金B經固溶處理後之SEM金相圖…………………………20 圖3.3 不同Sc及Zr含量之Al-Cu-Mg-Ag合金經均質化處理後 之金相圖………………………………………………………22 圖3.4 不同Sc及Zr含量之Al-Cu-Mg-Ag合金經固溶處理 之金相圖及晶粒結構…………………………………………23 圖3.5 合金A、B、C經固溶處理、自然時效一天後 之DSC曲線……………………………………………………26 圖3.6 合金B、C經固溶處理、自然時效一天後,以20℃/min 升溫至400℃後水淬之TEM影像圖與繞射圖………………28 圖3.7 合金A、B、C於T7人工時效後之TEM影像圖 與繞射圖………………………………………………………29 圖3.8 合金A、B、C於固溶處理後、自然時效一天 及人工時效處理之導電度曲線(%IACS) ……………………31 圖3.9 合金A、B、C經185℃×5hr(T7)處理後之拉伸破斷面…………36 圖3.10 合金A、B、C經固溶處理、自然時效一天及 人工時效處理之硬度曲線……………………………………37 表目錄 表2.1 實驗配製之Al-Cu-Mg-Ag合金成分…………………………14 表3.1 合金A、B、C經固溶處理後,基地處Cu、Sc元素含量 之電子微探儀(EPMA)分析結果………………………………24 表3.2 合金A、B、C於固溶處理、自然時效一天後, Ω相及θ’相析出熱量及析出峰值溫度………………………28 表3.3 合金A、B、C於固溶處理後、自然時效一天 及人工時效處理後之導電度量測值(%IACS) ………………31 表3.4 合金A、B、C於固溶處理、自然時效一天 及人工時效處理後之硬度量測值(HRB) ……………………34 表3.5 合金A、B、C經185℃×5hr(T7)處理後之拉伸性質……………36

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