無鎳高氮不銹鋼中錳含量對孔蝕性質影響之研究

Yu-Lun Ke; 柯宇倫

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/23737

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	連雙喜
dc.contributor.author	Yu-Lun Ke	en
dc.contributor.author	柯宇倫	zh_TW
dc.date.accessioned	2021-06-08T05:09:32Z	-
dc.date.copyright	2011-07-29
dc.date.issued	2011
dc.date.submitted	2011-07-22
dc.identifier.citation	[1] J.J. Eckenrod ; New Development in S.S Technology Conference Proceedings, Edited by R.A. Lula, pp.77-87 [2] M.L.G. Byrnes, M. Grujicic and W.S. Owen ; Aeta Metall., 35 (1987), pp.1853. [3] R.P. Reed ; J. Metals, March (1989), 16 [4] M. Kikuchi, M Kajihara and K. Frisk ; Solubility of nitrogen in austenitic stainless steels, in J. Foct and A. Hendry (eds.), HNS 88, Lille, France, May 1988, The Institute of Metals, London, 1989, pp. 63. [5] M.O. Speidel and R.M. Pedrazzoli ; Mater. PerJorm., 31 (1992),59 [6] J.W. Simmons ; High-nitrogen alloying of stainless steels, Microstructural Science, Vol. 21, ASM International, Metals Park, OH, (1994), pp. 33. [7] J.H. Andrew ; “Nitrogen in Iron”, Carnegie Scholarship Memoirs, Vol. 11, 1912, pp. 236. [8] J.J. Adcock ; Iron and Steels Inst, Vol. 114, 1926, pp. 119. [9] H.H. Uhlig ; Trans Am Soc. Met, Vol. 30, 1942, pp. 947. [10] U. K. Mudali ; B. Raj, High nitrogen steels and stainless steels, (2004), pp. 4,6 [11] H. Bernes ; ISIJ Inter, Vol. 36, 1996, pp. 909. [12] G. Stein and I. Hucklenbroich ; Materials and Manufacturing Processes, Vol. 19, No. 1, pp. 7-17, 2004. [13] O.P. Sinha and R.C. Gupta ; ISIJ International, Vol. 33(1993), No.5, pp. 567-576. [14] G. Torkov et al.; J. Metals, Vol. 30, 1978, 12, pp. 20-27. [15] J. C. Rawers, L. J. Rawers ; J. Mat. Sci. Latters, 10 (1991) pp. 1101-02 [16] G. F. Torkhov, Yu. V. Latash, R. R.Fessler ; J. Metal, Dec. (1978), pp. 20-26 [17] G.M. Janowski, F.S. Biancaniello and S.D. Ridder ; Metall. Trans. A, 23 (1992), pp. 3263-3272 [18] P.J. Uggowitzer, W.F. Bahre, H. Wohlfromm and M.O. Spiedel ; Material Science Forum, Vols.318-320, 1999, pp. 663-672. [19] R.W.K. Honeycombe ; Steels Microstructure and Properties, 1986, pp. 273-303. [20] Metal Handbook 9th ed, Vol. 3, ASM, 1980. [21] D. J. Dyson and B. Holmes ; Effect of Alloying Additions on the lattice Parameter of Austenite, Journal of the Iron and Steel Institute, (1970) May, pp. 469-474. [22] E. Folkhard et al. ; Welding Metallurgy of Stainless Steel, Springer-Verlag Wien, 1988. [23] B. Baroux, Ph Maitrepierre and B. Thomas ; Stainless Steels (1984), pp. 115. [24] T. Takemoto, Y. Murata and T. Tanaka ; ISIJ International, (1990) Vol. 30, No.8, pp. 608-614. [25] Donald Peckner and I. M. Bernstein ; Handbook of Stainless Steels, McGrawHill book Company, Chapter 14, (1977), pp. 14-9-11. [26] A.H. Satir-Kolorz and H.K. Feichtinger ; Z. Metallkde, 82 (1991), 689. [27] J.C. Rawers, N.A. Gokcen and R.D. Pehlke ; Metall. Trans. A, 24 (1993), 73. [28] J.R. Davis ; ASM Specialty Handbook 'Stainless steels', ASM International, (1994), 13. [29] F.C. Hull ; Weld. J., 52 (1973), 193. [30] Shahriar Sharafi ; St. Edmund College, University of Calnbridge, September (1993), 42. [31] D. Seferian ; Metallurgie de la Soudure, Dunod, Paris (1959). [32] F.B. Pickering ; Conf. Proc. Stainless Steel'84, (1984), 2. [33] K. Skuin and T. Kreyssing ; Neue Hutte, 23 (1978), 22. [34] J. Honeycombe and T.G. Gooch ; The Weld Inst., UK, Report (1985), 286. [35] N. Suntala, T. Takalo and T. Mosio ; Met. Trans., 10A (1979), 513. [36] D.N. Noble and T.G. Gooch ; The Weld Inst., UK, Report (1986), 321. [37] Y. Machara ; Metal Science, 17 (1983), 541. [38] O. Hammar and U. Svensson ; Proceedings of Inter. Conf. of Solidification and Casting of Metals, UK (1979), 401. [39] T. Sakamoto, H. Abo, T. Okazaki, T. Ogawa and T. Zaizen ; Alloys of Eighties, Climax molybdenum Company, Ann Arbor, (1980), 269. [40] K. Zagorski an A. Doraczynska ; Corrosion Science, 16 (1976), 405. [41] Y.C. Liu, M.B Ives and C.R. Clayton ; Corrosion Science, 35 (1993), 89. [42] F.M. Bayumin and W.A. Ghanem ; Materials Letters, 59 (2005) 3311. [43] M.O. Speidel, in : Proceedings of Inter. Conf. of Solidification and Casting of Metals, ISIJ, Chiba (1991), 25. [44] U.K. Mudali and S. Ningshen, in : U.K. Mudali, B. Raj(Eds.), High Nitrogen Steels and Stainless Steels - Manufaturing Properties and Applications, Alpha Science Inter. Ltd., UK, (2004), 133. [45] G.C. Palit, V. Kain and H.S. Gidaryar ; Corrosion 49 (1993), 977. [46] H. Baba, T. Kodama and Y. Katada ; Corrosion Science, 44 (2002), 2393. [47] I. Olefjord and L. Wergrelius ; Corrosion Science, 38 (1996), 1203. [48] S. Azuma, H. Miyuki and K. Kudo ; ISIJ Internatuonal, 36 (1996), 793. [49] H. Yashiro, D. Hirayasu and N. Kumagai ; ISIJ Internatuonal, 42 (2002), 1477. [50] L. Vehovar, A. Vehovar, M. Metikos-Hukovic and M. Tandler ; Materials and Corrosion, 53 (2002), 316. [51] W.T. Tsai, B. Reynders, M. Strattman and H.J. Garbke ; Corrosion Science, 34 (1993), 1647. [52] C.R. Clayton, L. Rosenzweig, M. Oversluizen and Y.C. Lu ; Proceedings of the Electrochemical Society, 86 (1986), 323. [53] M.B. Ives, Y.C. Lu and J.L. Luo ; Corrosion Science, 32 (1991), 91. [54] H. Baba and Y. Katada ; Corrosion Science, 48 (2006), 2510. [55] T. Misawa and H. Tanabe ; ISIJ Internatuonal, 36 (1996), 787. [56] Y. Lu, R. Brandy, C.R. Clayton and R.C. Newman ; Journal of Electrochemical Society, 130 (1983), 1774. [57] H.J. Garbke ; ISIJ Internatuonal, 36 (1996), 777. [58] C.-O.A. Olsson, Corrosion Science, 37 (1995), 467. [59] A.S. Vanini, J.P. Audouard and P. Marcus ; Corrosion Science, 36 (1994), 1825. [60] G. Lothongkum, P. Wonpangya, S. Morito, T. Furuhara and T. Maki ; Corrosion Science, 48 (2006), 137. [61] U.K. Mudali and R.K. Dayal, Journal of Material Science, 35 (2000), 1799. [62] M.O. Speidel and R.M. Pedrazzoli ; Mater. PerJorm., 31 (1992), 59. [63] P.J. Uggowitzer, R. Magdowski and M.O. Speidel ; Metall. Inter., 86 (1994), 347. [64] U. K. Mudali, P. Shankar, S. Ningshen, R.K. Dayal H.S. Khatak and B. Raj ; Corrosion Science, 44 (2002), 2183. [65] J. Steward and D.E. Williams ; Corrosion Science, 33 (1992), 457. [66] S. Maximovitch, G. Barral, F. Le Cras and F. Claudet ; Corrosion Science ; 37 (1995), 271. [67] A. Pardo, M.C. Merino, A.E. Coy, F. Viejo, A. Arrabal and E. Matikyna ; Corrosion Science, 50 (2008), 1796. [68] R.F.A. Jargelius-Pettersson ; ISIJ International, 36 (1996), 818. [69] K.J. Park and H.S. Kwon ; Electrochimica Acta, 55 (2010), 3421. [70] L. Reclura, R. Lerf, P.Y. Eschler, A. Blatter and J.M. Meyer ; Biomaterials, 23 (2002), 3479. [71] H.J. Yang, K. Yang and B.C. Zhang ; Materials Letters, 61 (2007), 1154. [72] T.H. Lee, C.S. Oh, C.G. Lee, S.J Kim and Setsuo Takaki ; Scripta Materialia, 50 (2004), 1325. [73] B.D. Cullity and S.R. Stock ; 'Elements of X-ray Diffraction, 3rd', Prentice Hall, 2001. [74] R.E. Napolitano ; 'Measurement of ASTM Grain Size Number', Department of Materials Science and Engineering, Iowa state, U.S.A. [75] A. Szummer and M. Janik-Czachor ; Corrosion Science, 35 (1993), 317. [76] B. Elsener, D. Addari, S. Coray and A. Rossi ; Electrochimica Acta, (2011), in press. [77] A. Iversen and B. Leffler ; Ferrous Metals and Alloys, (2010), 1826. [78] 林奕丞 ; 無鎳高氮不銹鋼之機械性質與生物相容性研究, 2009. [79] M. Kikuchi, M. Kajihara and S.K. Choi ; Materials Science and Engineering A, 146 (1991), 131. [80] N.C. Santhi Shrinivas and V.V. Kutumbarao ; Scripta Materialia, 37 (1997), 285. [81] F. Shi, L.J. Wang, W.F. Cui and C.M. Liu ; Journal of Iron and Steel Research, International, 15 (2008), 72. [82] M. Dadfar, M.H. Fathi, F. Karimzadeh, M.R. Dadfar and A. Saatchi ; Materials letters, 61 (2007), 2343.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/23737	-
dc.description.abstract	本研究利用合金設計的方式，嘗試以低氮壓電弧熔煉爐製備不同錳含量之Fe-15Cr-12~22Mn-2.8Mo無鎳高氮不銹鋼，發現當錳含量增加時，合金的氮含量也隨之增加，可得到最高之氮含量約為1.4wt%，且完全不具磁性的單一沃斯田鐵相結構。鑄錠經裁切後分別以50%及75%軋延量於1150℃進行熱輥軋，得到晶粒大小不同的兩組試片，接著於3.5wt% NaCl溶液中，以0.3mV之掃描速率，分別進行動態極化掃描試驗。結果發現，氮含量較高的試片，孔蝕電位也較高。50%軋延量下，試片經電化學腐蝕測試後的結果與其錳含量有關，錳含量高於鉻含量的試片鈍化效果並不明顯，且孔洞於合金內部的擴散能力強，在表面形成佈滿細小孔洞的薄層；錳含量低於鉻含量的試片鈍化效果較為明顯，其孔洞於局部漸漸成長，顯見合金的錳含量對於鈍化層的形層的形成有不良影響，進而使得合金抗腐蝕能力下降。對此現象，本研究提出合理的模型，並與過去的研究相互得到應證。75%軋延量下，由於晶粒較小，晶界面積增加，腐蝕首先發生在晶界，且部分合金於晶界處產生層狀的Cr2N析出物，此析出物的生成溫度約在800~900℃間，此析出物對於機械以及抗腐蝕性有害，熱輥軋時必須注意溫度的控制以避免其生成。此外，活性元素(SAE)如硫元素，其含量越多，熔煉後合金的氮含量越少，故製備無鎳高氮不銹鋼時，須注意原料的清淨度，以確保能達到較高的氮含量。	zh_TW
dc.description.abstract	Different compositions of nickel free high nitrogen stainless steels (Fe-15Cr-12~22 Mn-2.8Mo-N) are prepared by low pressure arc melting process, nitrogen content is increased with Mn addition from 0.34wt% to 1.4wt%. Ingots are properly cut and hot-rolled under 1150℃ to 50% and 25% of their original thickness. The potentiadynamic polarization measurement were performed in a conventional three electrode cell with 3.5wt% NaCl medium. The result shows that pitting corrosion potential increased with nitrogen content. For 50% hot-rolled samples, pit morphology vary with their Mn content : in higher Mn content ones, pits growth beneath the surface toward some specific direction, left extensive lace-like cover region; in lower ones, pits tend to growth locally by etching grains, lace-like cover region is relatively small. Hence, the passivity and corrosion properties of stainless steels is sensitive to Mn content. For 75% hot-rolled samples, corrosion tends to start from grain boundaries, and in some cases, Cr2N precipitates from grain boundaries, it can be avoided be by carefully temperature control. Nitrogen content varies with different sulfur level, surface active element (SAE) like sulfur should be removed before or during melting.	en
dc.description.provenance	Made available in DSpace on 2021-06-08T05:09:32Z (GMT). No. of bitstreams: 1 ntu-100-R97527031-1.pdf: 15035842 bytes, checksum: 04259a6b18a2c2ae1eeaee13ad32d233 (MD5) Previous issue date: 2011	en
dc.description.tableofcontents	一、前言 1 第二章文獻回顧 3 2.1 高氮不銹鋼的發展 3 2.1.1 Conventional Melting and Alloying 4 2.1.2 Plasma Arc Remelting under Pressure 4 2.1.3 Electroslag Remelting under Pressure 4 2.1.4 Powder Metallurgy 5 2.2 合金元素對不銹鋼之影響 8 2.3 合金中的氮含量 10 2.3.1 壓力對氮含量的影響 10 2.3.2 合金設計對氮含量的影響 11 2.3.3 含氮合金的鉻、鎳當量 11 2.4 不銹鋼的腐蝕性質 15 2.4.1 一般不銹鋼的腐蝕性質 15 2.4.2 金屬的電化學腐蝕性質 15 2.4.2.1 測量合金抗腐蝕性質的方法 16 2.4.2.2 電化學極化原理 16 2.4.2.3 混合電位原理 18 2.4.2.4 動態極化曲線 19 2.4.3 含氮不銹鋼孔蝕現象 19 2.4.4 氮元素對於不銹鋼腐蝕性質的影響 20 2.4.5 其他元素對於不銹鋼腐蝕性質的影響 21 2.5 本研究之目的 27 第三章實驗步驟與方法 28 3.1 合金相圖模擬 28 3.1.1 熱力學相圖模擬 28 3.1.2 Schaeffler-Delong Diagram 28 3.2 合金熔煉及後續加工處理 29 3.2.1 合金配製 29 3.2.2 低氮壓電弧爐合金熔煉 30 3.2.3 鑄錠熱輥軋處理 30 3.3 合金性質分析 31 3.3.1 合金成份分析 31 3.3.2 氧氮與硫碳含量分析 31 3.3.3 合金肥粒鐵含量分析 31 3.3.4 光學顯微鏡分析 31 3.3.5 掃描式電子顯微鏡分析 32 3.3.6 XRD繞射分析 32 3.3.7 電化學腐蝕實驗 32 第四章結果與討論 38 4.1 合金相圖模擬與金相 38 4.1.1 合金相圖模擬結果 38 4.1.2 金相與XRD結果 44 4.1.3 合金的鉻鎳當量結果 56 4.1.4 熱輥軋與晶粒大小 58 4.2 電化學腐蝕測試 61 4.2.1 合金的腐蝕性質 61 4.2.2 錳含量對合金鈍化能力的影響 66 4.2.3 錳含量對合金孔蝕性質的影響 72 4.2.3.1 50%軋延量下孔蝕洞之形成機制 72 4.2.3.2 75%軋延量下孔蝕洞之形成機制 78 4.3 活性元素對合金氮含量的影響 82 第五章結論 85 第六章參考文獻 86
dc.language.iso	zh-TW
dc.title	無鎳高氮不銹鋼中錳含量對孔蝕性質影響之研究	zh_TW
dc.title	Effects of Mn Content on the Pitting Corrosion Behavior of Nickel Free High Nitrogen Stainless Steels	en
dc.type	Thesis
dc.date.schoolyear	99-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	鄭國華,蔡文達,劉宏義
dc.subject.keyword	無鎳高氮不銹鋼,低氮壓電弧熔煉,氮含量,高錳含量,鈍化,孔蝕,活性元素,	zh_TW
dc.subject.keyword	nickel free,low pressure arc melting,nitrogen content,high manganese,passivity,SAE,	en
dc.relation.page	90
dc.rights.note	未授權
dc.date.accepted	2011-07-25
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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