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| ???org.dspace.app.webui.jsptag.ItemTag.dcfield??? | Value | Language |
|---|---|---|
| dc.contributor.advisor | 薛人愷 | zh_TW |
| dc.contributor.advisor | Ren-Kae Shiue | en |
| dc.contributor.author | 朱弘揚 | zh_TW |
| dc.contributor.author | Hung-Yang Chu | en |
| dc.date.accessioned | 2026-04-30T16:18:46Z | - |
| dc.date.available | 2026-05-01 | - |
| dc.date.copyright | 2026-04-30 | - |
| dc.date.issued | 2026 | - |
| dc.date.submitted | 2026-04-08 | - |
| dc.identifier.citation | References
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Nuclear engineering and design, 2005. 235(23): p. 2485-2494. | - |
| dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/102293 | - |
| dc.description.abstract | 309L與316L均屬於300系列沃斯田鐵不銹鋼。其沃斯田鐵基地相(Austenitic matrix)內的δ-ferrite和σ相形態與後續熱抽和冷抽之製程密切相關,在高溫下δ-ferrite相易轉變成σ相,σ相為脆性金屬間相(Brittle intermetallic phase)且有高硬度,此為導致盤元(wire rod)後續抽線發生斷裂的主因。本研究旨在尋找可行的冶金路徑,避免鑄胚(cast billet)在熱抽形成8 mm盤元以及後續加工抽線成0.8 ~1.2 mm線材時發生斷裂,以供華新麗華公司後續於鹽水軋機生產高Cr/Ni 沃斯田鐵不銹鋼線材時其製程參數的優化。
本研究針對兩種連鑄鋼胚,分別取其中心處(C)、半徑處(0.5R)與近表面處(R),於1240 °C下進行2小時空冷(快速冷卻)與6小時均質化爐冷(緩慢冷卻)熱處理,並使用場發射掃描式電子顯微鏡結合背向散射電子繞射(EBSD)功能、場發射電子微探儀(FE-EPMA)配備波長分光光譜儀(WDS)以及維克氏微硬度計(Vickers micro-hardness tester),系統性觀察在均質化熱處理前後其硬度、分佈、形態、數量、化學成分與相變態演變機制。 研究結果顯示,均質化熱處理提供了δ-ferrite球化之驅動力,當均質化持溫時間由2小時延長至6小時,能有效促進δ-ferrite之形貌球化。此外,δ-ferrite與σ相間的相變態受溫度與冷卻速率顯著影響,於1240 °C持溫2小時後空冷可有效抑制σ相析出;於1240 °C持溫6小時爐冷,高合金沃斯田鐵不銹鋼309L與316L,δ-ferrite會相變析出σ相。 為精確控制相組成,研究進一步針對309L與316L進行不同溫度的冷卻實驗。結果顯示,309L須於600 °C至850 °C區間進行空冷以避開σ相形成區間;316L則須於較高溫之850 °C至1240 °C區間進行空冷,才能抑制σ相形成。 | zh_TW |
| dc.description.abstract | Both 309L and 316L are members of the 300-series austenitic stainless steels. The morphology of δ-ferrite and σ phase within the austenitic matrix is highly sensitive to subsequent hot rolling and cold drawing. At elevated temperatures, δ-ferrite is prone to transforming into the σ phase, a brittle intermetallic phase with high hardness, which is the primary cause of fracture during wire rod drawing. This study aims to identify a feasible metallurgical pathway to prevent fracture during the hot rolling of cast billets into 8 mm wire rods and the subsequent drawing into 0.8–1.2 mm wires. The findings inform the optimization of process parameters at Walsin Lihwa Corporation for the production of high-Cr/Ni austenitic stainless steel ultrafine wires.
In this study, specimens were sampled from three distinct locations on the continuous-cast billets: the center (C), mid-radius (0.5R), and near-surface (R). Heat treatments were conducted at 1240 °C for 2 hours via air cooling (rapid cooling) and for 6 hours via furnace cooling (slow cooling). FESEM-EBSD (Field Emission Scanning Electron Microscopy combined with Electron Backscatter Diffraction), EPMA (Field Emission Electron Probe Microanalyzer) equipped with WDS (Wavelength Dispersive Spectroscopy), and Vickers micro-hardness tester were employed to observe the evolution of hardness, distribution, morphology, volume fraction, chemical composition, and phase transformation mechanisms before and after homogenization. The results indicate that homogenization heat treatment drives the spheroidization of δ-ferrite. Extending the homogenization time from 2 to 6 hours effectively promotes the spheroidization of δ-ferrite. Furthermore, the experimental results showed that temperature and cooling rate dominate the phase transformation mechanism between δ-ferrite and σ phase. Air cooling after a 2-hour hold at 1240 °C effectively suppresses σ phase formation. Conversely, during furnace cooling after a 6-hour hold at 1240 °C, the δ-ferrite in high-alloy 309L and 316L decomposes into σ phase. To suppress σ phase formation, cooling experiments were conducted at various temperature intervals for both 309L and 316L. The results showed that rapid cooling must be applied at a temperature between 600 °C and 850 °C in 309L, whereas 316L requires rapid cooling at high temperatures between 850 °C and 1240 °C to avoid σ formation. | en |
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| dc.description.provenance | Made available in DSpace on 2026-04-30T16:18:46Z (GMT). No. of bitstreams: 0 | en |
| dc.description.tableofcontents | 口試委員審定書 i
學位論文學術倫理暨原創性聲明書 ii 誌謝 iii 摘要 iv Abstract v 目次 vii 圖次 xiv 表次 xxviii 第一章 前言 1 第二章 文獻回顧與研究方法 2 2-1 300系列沃斯田鐵不銹鋼介紹 2 2-2 Fe-Cr-Ni三元合金系統 4 2-3 σ相的相變機制 12 2-4 謝夫列爾組織圖(Schaeffler diagram) 15 第三章 實驗流程 16 3-1 實驗目的 16 3-2 試樣製備 17 3-3 實驗方法 18 3-3-1 均質化處理 18 3-3-2 金相研磨與拋光 25 3-4 分析儀器 28 3-4-1 FE-SEM/EBSD 28 3-4-2 FE-EPMA/WDS 31 3-4-3 Vickers micro-hardness test 33 第四章 結果與討論 34 4-1 鑄態 34 4-1-1 309L-C 34 4-1-1-1 相演變與顯微結構組織觀察 34 4-1-1-2 定量打點與元素mapping分析 35 4-1-1-3 微硬度分析 35 4-1-2 309L-0.5R 36 4-1-2-1 相演變與顯微結構組織觀察 36 4-1-2-2 定量打點與元素mapping分析 36 4-1-2-3 微硬度分析 37 4-1-3 309L-R 37 4-1-3-1 相演變與顯微結構組織觀察 37 4-1-3-2 定量打點與元素mapping分析 38 4-1-3-3 微硬度分析 38 4-1-4 316L-C 39 4-1-4-1 相演變與顯微結構組織觀察 39 4-1-4-2 定量打點與元素mapping分析 39 4-1-4-3 微硬度分析 40 4-1-5 316L-0.5R 40 4-1-5-1 相演變與顯微結構組織觀察 40 4-1-5-2 定量打點與元素mapping分析 41 4-1-5-3 微硬度分析 41 4-1-6 316L-R 42 4-1-6-1 相演變與顯微結構組織觀察 42 4-1-6-2 定量打點與元素mapping分析 42 4-1-6-3 微硬度分析 43 4-2 1240 °C持溫2小時均質化熱處理-空冷 68 4-2-1 309L-C-1240-2h-AC 68 4-2-1-1 相演變與顯微結構組織觀察 68 4-2-1-2 定量打點與元素mapping分析 68 4-2-1-3 微硬度分析 69 4-2-2 309L-0.5R-1240-2h-AC 69 4-2-2-1 相演變與顯微結構組織觀察 69 4-2-2-2 定量打點與元素mapping分析 69 4-2-2-3 微硬度分析 70 4-2-3 309L-R-1240-2h-AC 70 4-2-3-1 相演變與顯微結構組織觀察 70 4-2-3-2 定量打點與元素mapping分析 71 4-2-3-3 微硬度分析 71 4-2-4 316L-C-1240-2h-AC 71 4-2-4-1 相演變與顯微結構組織觀察 71 4-2-4-2 定量打點與元素mapping分析 72 4-2-4-3 微硬度分析 72 4-2-5 316L-0.5R-1240-2h-AC 73 4-2-5-1 相演變與顯微結構組織觀察 73 4-2-5-2 定量打點與元素mapping分析 73 4-2-5-3 微硬度分析 74 4-2-6 316L-R-1240-2h-AC 74 4-2-6-1 相演變與顯微結構組織觀察 74 4-2-6-2 定量打點與元素mapping分析 74 4-2-6-3 微硬度分析 75 4-3 1240 °C持溫6小時均質化熱處理-爐冷 102 4-3-1 309L-C-1240-6h-FC 102 4-3-1-1 相演變與顯微結構組織觀察 102 4-3-1-2 定量打點與元素mapping分析 103 4-3-1-3 微硬度分析 103 4-3-2 309L-0.5R-1240-6h-FC 104 4-3-2-1 相演變與顯微結構組織觀察 104 4-3-2-2 定量打點與元素mapping分析 104 4-3-2-3 微硬度分析 105 4-3-3 309L-R-1240-6h-FC 105 4-3-3-1 相演變與顯微結構組織觀察 105 4-3-3-2 定量打點與元素mapping分析 105 4-3-3-3 微硬度分析 106 4-3-4 316L-C-1240-6h-FC 106 4-3-4-1 相演變與顯微結構組織觀察 106 4-3-4-2 定量打點與元素mapping分析 107 4-3-4-3 微硬度分析 107 4-3-5 316L-0.5R-1240-6h-FC 108 4-3-5-1 相演變與顯微結構組織觀察 108 4-3-5-2 定量打點與元素mapping分析 108 4-3-5-3 微硬度分析 109 4-4 309L & 316L-0.5R-1240-2h-FC, AC 130 4-4-1 309L-0.5R-1240-2h-FC 130 4-4-1-1 相演變與顯微結構組織觀察 130 4-4-1-2 定量打點與元素mapping分析 130 4-4-1-3 微硬度分析 131 4-4-2 316L-0.5R-1240-2h-FC 131 4-4-2-1 相演變與顯微結構組織觀察 131 4-4-2-2 定量打點與元素mapping分析 132 4-4-2-3 微硬度分析 132 4-5 309L-0.5R-1050-2h-FC, AC vs 309L-0.5R-1240-2h-FC, AC 142 4-5-1 309L-0.5R-1050-2h-FC 142 4-5-1-1 相演變與顯微結構組織觀察 142 4-5-1-2 定量打點與元素mapping分析 142 4-5-1-3 微硬度分析 143 4-5-2 309L-0.5R-1050-2h-AC 143 4-5-2-1 相演變與顯微結構組織觀察 143 4-5-2-2 定量打點與元素mapping分析 144 4-5-2-3 微硬度分析 144 4-6 309L & 316L 0.5R-1240-2h-FC-850, 600-AC 154 4-6-1 309L-0.5R-1240-2h-FC-850-AC 154 4-6-1-1 相演變與顯微結構組織觀察 154 4-6-1-2 定量打點與元素mapping分析 155 4-6-1-3 微硬度分析 155 4-6-2 309L-0.5R-1240-2h-FC-600-AC 155 4-6-2-1 相演變與顯微結構組織觀察 155 4-6-2-2 定量打點與元素mapping分析 156 4-6-2-3 微硬度分析 156 4-6-3 316L-0.5R-1240-2h-FC-850-AC 157 4-6-3-1 相演變與顯微結構組織觀察 157 4-6-3-2 定量打點與元素mapping分析 157 4-6-3-3 微硬度分析 158 4-6-4 316L-0.5R-1240-2h-FC-600-AC 158 4-6-4-1 相演變與顯微結構組織觀察 158 4-6-4-2 定量打點與元素mapping分析 158 4-6-4-3 微硬度分析 159 第五章 Thermo-Calc 模擬 177 5-1 309L Thermo-Calc模擬 177 5-1-1 309L Isothermal section at 1440 °C 177 5-1-2 309L Isothermal section at 1415 °C 177 5-1-3 309L Isothermal section at 1390 °C 177 5-1-4 309L Isothermal section at 1340 °C 178 5-1-5 309L Isothermal section at 1290 °C 178 5-1-6 309L Isothermal section at 1240 °C 179 5-1-7 309L Isothermal section at 1190 °C 179 5-1-8 309L Isothermal section at 1140 °C 179 5-1-9 309L Isothermal section at 1090 °C 180 5-1-10 309L Isothermal section at 1040 °C 180 5-1-11 309L Isothermal section at 940 °C 180 5-1-12 309L Isothermal section at 840 °C 181 5-1-13 309L Isothermal section at 740 °C 181 5-1-14 309L Isothermal section at 640 °C 181 5-1-15 309L Isothermal section at 540 °C 182 5-2 316L Thermo-Calc模擬 208 5-2-1 316L Isothermal section at 1440 °C 208 5-2-2 316L Isothermal section at 1415 °C 208 5-2-3 316L Isothermal section at 1390 °C 209 5-2-4 316L Isothermal section at 1340 °C 209 5-2-5 316L Isothermal section at 1290 °C 210 5-2-6 316L Isothermal section at 1240 °C 210 5-2-7 316L Isothermal section at 1190 °C 211 5-2-8 316L Isothermal section at 1140 °C 211 5-2-9 316L Isothermal section at 1090 °C 211 5-2-10 316L Isothermal section at 1040 °C 212 5-2-11 316L Isothermal section at 940 °C 212 5-2-12 316L Isothermal section at 840 °C 212 5-2-13 316L Isothermal section at 740 °C 213 5-2-14 316L Isothermal section at 640 °C 213 5-2-15 316L Isothermal section at 540 °C 213 第六章 總結 241 參考文獻 243 | - |
| dc.language.iso | zh_TW | - |
| dc.subject | 均質化熱處理 | - |
| dc.subject | 沃斯田鐵不銹鋼 | - |
| dc.subject | 鑄胚 | - |
| dc.subject | 抽線 | - |
| dc.subject | δ-ferrite | - |
| dc.subject | σ phase | - |
| dc.subject | Homogenization heat treatment | - |
| dc.subject | austenitic stainless steel | - |
| dc.subject | cast billet | - |
| dc.subject | wire drawing | - |
| dc.subject | δ-ferrite | - |
| dc.subject | σ phase | - |
| dc.title | 300系列沃斯田鐵不銹鋼鑄胚均質化冶金技術研究 | zh_TW |
| dc.title | Investigation of Homogenization Metallurgical Techniques for 300-Series Austenitic Stainless Steel Cast Billets | en |
| dc.type | Thesis | - |
| dc.date.schoolyear | 114-2 | - |
| dc.description.degree | 博士 | - |
| dc.contributor.oralexamcommittee | 蔡履文;郭東昊;張書維;黃亮維 | zh_TW |
| dc.contributor.oralexamcommittee | Leu-Wen Tsay;Dong-Hau Kuo;Shu-Wei Chang;Liang-Wei Huang | en |
| dc.subject.keyword | 均質化熱處理,沃斯田鐵不銹鋼鑄胚抽線δ-ferriteσ phase | zh_TW |
| dc.subject.keyword | Homogenization heat treatment,austenitic stainless steelcast billetwire drawingδ-ferriteσ phase | en |
| dc.relation.page | 249 | - |
| dc.identifier.doi | 10.6342/NTU202600905 | - |
| dc.rights.note | 同意授權(全球公開) | - |
| dc.date.accepted | 2026-04-08 | - |
| dc.contributor.author-college | 工學院 | - |
| dc.contributor.author-dept | 材料科學與工程學系 | - |
| dc.date.embargo-lift | 2026-05-01 | - |
| Appears in Collections: | 材料科學與工程學系 | |
Files in This Item:
| File | Size | Format | |
|---|---|---|---|
| ntu-114-2.pdf | 45.45 MB | Adobe PDF | View/Open |
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