JIS SK5及JIS S60C鋼之變韌鐵組織與其它組織的性質比較

Meng-Yin Tu; 涂孟寅

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/31363

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	王文雄(Wen-Hsiung Wang)
dc.contributor.author	Meng-Yin Tu	en
dc.contributor.author	涂孟寅	zh_TW
dc.date.accessioned	2021-06-13T02:45:35Z	-
dc.date.available	2007-10-25
dc.date.copyright	2006-10-25
dc.date.issued	2006
dc.date.submitted	2006-10-18
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/31363	-
dc.description.abstract	本研究目的在探討JIS SK5及JIS S60C兩種鋼材經不同熱處理後之顯微組織及機械性質。此外也對其上、下變韌鐵的破壞行為進行解析，並觀察變韌鐵變態的過程及其相變態的晶體學。實驗結果顯示，SK5及S60C兩種鋼材之上、下變韌鐵組織的延、韌性較同硬度的回火麻田散鐵組織者佳。與下變韌鐵組織硬度相同之回火麻田散鐵，由於發生回火麻田散鐵脆性（TME），其韌性遠低於下變韌鐵，其破斷面呈沿晶破裂的模式，經歐傑能譜儀對破斷面分析，發現有不純物磷偏析至晶界造成晶界弱化。碳化物是影響所有組織機械性質最主要的因素，於變韌鐵組織中，含碳量高者，其受碳化物分散強化的影響越大，使材料之強度、硬度提升，而韌性下降。上、下變韌鐵的破斷面皆呈穿晶劈裂破壞，其劈裂刻面尺寸與變韌鐵束尺寸間有對應關係。經EBSD”直接分析法”量測發現劈裂面晶體方位趨向{001}α、{112}α及{123}α等面上，這些晶面都是破裂裂紋傳遞時偏好的低表面能劈裂路徑。理論計算結果顯示變韌鐵束界面大多屬於高角度晶界，因此裂紋會在變韌鐵束界面作路徑的偏折，證實變韌鐵束尺寸即為劈裂路徑的單位尺寸。上、下變韌鐵之肥粒鐵/雪明碳鐵間呈Bagaryatskii方位關係，組織中的雪明碳鐵會析出於面上。而沃斯田鐵/肥粒鐵的方位關係則介於K-S與N-W之間。變韌肥粒鐵長條之兩組平行四邊形切面分別座落於 ~ 及面上。結合變韌鐵中沃斯田鐵/肥粒鐵/雪明碳鐵三者方位關係及恆溫變態的組織觀察，可將變韌鐵之成長過程描述為：（a）變韌肥粒鐵次平板（subunit）或次次平板（sub subunit）在沃斯田鐵相的(111)γ	zh_TW
dc.description.abstract	面上生核且沿著 ~ 方向生長。（b）變韌鐵次平板會叢聚一起，開始了擴散行為，使面傾向於面。變韌肥粒鐵於晶癖面上析出雪明碳鐵，兩相間具有Bagaryatskii方位關係；（c）隨恆溫變態時間增加，肥粒鐵次平板不斷生核成長且叢聚成變韌鐵束，將雪明碳鐵包埋在其中。	zh_TW
dc.description.abstract	This study investigates the microstructures and mechanical properties of various structures in JIS SK5 and JIS S60C steels. Strength falls and ductility raises as carbon content in steels increases for all structures. At equivalent hardness, the toughness and ductility of bainite are superior to those of tempered martensite. Tempered martensite embrittlement (TME) occurred in the ~310℃ tempered specimens, whose hardness is equal to lower bainite one. It is caused by grain boundary segregation of phosphorus and grain boundary precipitation of carbide during tempering. The fracture mode of TME is dominated by intergranular failure. The fracture surfaces of both lower and upper bainite structures exhibit transgranular cleavage. The size of the cleavage facet of bainite was demonstrated to be correlated with the width of the bainite sheaf. The results of EBSD analysis indicates not only that the sheaf boundary is a high-angle boundary, but also that the cleavage crack travels along the {001}α, {112}α and {123}α ferrite planes, whose surface energy are low. According to TEM diffraction analysis, the orientation relationship of cementite / bainitic ferrite satisfies the Bagaryatskii relation, and the habit plane of cementite precipitated in the bainite sheaf locates on	en
dc.description.abstract	. The orientation relationship of austenite / bainitic ferrite satisfies between K-S and N-W relation. Two sets of parallelogram cross-section of binitic ferrite were found to locate on ~ and respectively. As isothermal holding time increases, one set of parallel plane inclines to via a diffusional interface migration and bainite subunits gradually coalesce.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T02:45:35Z (GMT). No. of bitstreams: 1 ntu-95-F89542014-1.pdf: 12944184 bytes, checksum: 691ffb73318ab3609e27f418770d729a (MD5) Previous issue date: 2006	en
dc.description.tableofcontents	摘要…………………………………………………………... Ⅰ Abstract...........................................Ⅲ 目錄…………………………………………………………..…Ⅴ 表目錄…………………………………………….……………Ⅷ 圖目錄…………………………………………….……………Ⅸ 第一章前言……………………………………………..1 第二章文獻回顧……………………………………………..4 2-1 熱處理……………………………………………..….4 2-1-1 沃斯回火處理…..………………………………….4 2-1-2 麻淬火熱處理………………………..…………….5 2-2 變韌鐵相變態………………………………………...5 2-2-1 上變韌鐵…………………………………………..8 2-2-2 下變韌鐵…………………………………………..9 2-2-3 變韌鐵變態的機制………...……………………...12 2-3 麻田散鐵相變化………………………………….…13 2-3-1 麻田散鐵的特徵…………………...…………...…14 2-3-2 麻田散鐵之晶體結構………………...……………15 2-3-3 麻田散鐵之結晶學………………..…………...….16 2-3-4 回火麻田散鐵脆性………………………….…….18 2-4 晶癖面、劈裂晶面及位錯的量測方法…………….19 2-4-1軌跡分析法（trace analysis）…………………...19 2-4-2 EBSD直接分析法……………………………………….21 2-4-3 位錯（misorientation）…………………………21 第三章實驗方法………………..…………………………..35 3-1 試片成份及製作………………………………….…35 3-2 熱處理…………………………………………….…35 3-2-1 沃斯回火…………………………………………36 3-2-2 傳統淬火回火…..………………..…………….…36 3-2-3 麻淬火回火…….………………...………….……36 3-3 機械性質測試………..……………………………...37 3-3-1 硬度測試……………………………………...….37 3-3-2 衝擊試驗…………………………………………37 3-3-3 拉伸試驗………………………………………....37 3-4 顯微組織觀察…………………………………….…38 3-4-1 光學顯微鏡之觀察.………………..……………....38 3-4-2 穿透式電子顯微鏡(TEM)之觀察…………………...38 3-5 衝擊破斷面之觀察……………………………….....39 3-5-1 掃瞄式電子顯微鏡(SEM)之觀察…………………...39 3-5-2 歐傑電子能譜儀（AES）之分析…………………..…39 3-6 EBSD分析…………………………………………...39 3-6-1 破斷劈裂刻面之晶體分析…………………………39 3-6-2 EBSD mapping…………………………………….39 第四章顯微組織與機械性質…………………………….44 4-1 顯微組織的觀察…………………………………….44 4-1-1 變韌鐵…………………………………………....44 4-1-2 波來鐵組織………………………………….……46 4-1-3 回火麻田散鐵組織………………………………..47 4-2 機械性質測試………………..……………………...49 4-2-1 上、下變韌鐵機械性質……………………….……50 4-2-2 變韌鐵與其它組織之機械性質比較………….…….53 4-3 破斷面觀察...................................55 4-3-1 變韌鐵之破斷面分析.........................55 4-3-2 其它組織之破斷面觀察.......................56 4-4 歐傑電子能譜儀之分析....................58 4-5 晶界碳化物………………………………………….60 第五章變韌鐵破壞行為…………………………………..95 5-1 劈裂面的結晶學………………………………….....95 5-2 變韌鐵束間的錯位關係（Misorientation）………..…97 5-3 碳化物的影響…………………………………….....99 5-4 變韌鐵組織的破壞機制…………………………...100 第六章變韌鐵之晶體學…………………………………107 6-1 變韌肥粒鐵/雪明碳鐵的方位關係……..…………107 6-2 變韌鐵束組織及晶癖面（habit plane）..…………...108 6-3 恆溫過程之顯微組織…..………..………………...110 6-4 沃斯田鐵/變韌肥粒鐵的方位關係及變韌肥粒鐵之晶癖面..112 6-5 變韌鐵成長的過程…………………………...……113 第七章結論………………………………………………...126 7-1 顯微組織與機械性質………………………..…….126 7-2 變韌鐵破壞行為……………………………….…..127 7-3 變韌鐵之晶體學…………………………...………128 參考文獻……………………………………………….…….130 附錄……….…………………………………………….…….136
dc.language.iso	zh-TW
dc.title	JIS SK5及JIS S60C鋼之變韌鐵組織與其它組織的性質比較	zh_TW
dc.title	Comparison of Microstructures and Properties between Bainite and other Structures in JIS SK5 and JIS S60C Steels	en
dc.type	Thesis
dc.date.schoolyear	95-1
dc.description.degree	博士
dc.contributor.oralexamcommittee	徐永富(Yung-Fu Hsu),吳錫侃(Shyi-Kaan Wu),楊哲人(Jer-Ren Yang),林招松(Lin Chao-Sung),陳煌(Huang-Chuan Chen)
dc.subject.keyword	JIS SK5,S60C,EBSD,變韌鐵,	zh_TW
dc.subject.keyword	JIS SK5,S60C,EBSD,Bainite,	en
dc.relation.page	143
dc.rights.note	有償授權
dc.date.accepted	2006-10-18
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	材料科學與工程學研究所	zh_TW
顯示於系所單位：	材料科學與工程學系

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