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水蒸汽影响氧化铝膜生长的研究新进展 |
邢琳琳,郑雁军,崔立山,孙茂虎,邵明增,卢贵武 |
中国石油大学(北京)材料科学与工程系 北京 102249 |
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PROGRESS OF WATER VAPOUR EFFECT ON GROWTH OF ALUMINA FORMING ALLOYS |
XING Linlin, ZHENG Yanjun, CUI Lishan, SUN Maohu, SHAO Mingzeng, LU Guiwu |
Departments of Materials Science and Engineering, China University of Petroleum, Beijing 102249 |
引用本文:
邢琳琳,郑雁军,崔立山,孙茂虎,邵明增,卢贵武. 水蒸汽影响氧化铝膜生长的研究新进展[J]. 中国腐蚀与防护学报, 2011, 31(6): 409-413.
GENG Lin-Lin,
ZHENG Yan-Jun,
CUI Li-Shan,
XUN Mao-Hu,
SHAO Meng-Ceng.
PROGRESS OF WATER VAPOUR EFFECT ON GROWTH OF ALUMINA FORMING ALLOYS. J Chin Soc Corr Pro, 2011, 31(6): 409-413.
链接本文:
https://www.jcscp.org/CN/
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https://www.jcscp.org/CN/Y2011/V31/I6/409
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[1] Horsley G, Cairns J. The inhibition of carbon deposition on stainless steel by prior selective oxidation [J]. Appl. Surf.Sci., 1984, 18(3): 273-286[2] Millward G R, Evans H E, Aindow M, et al. The influence of oxide layers on the initiation of carbon deposition on stainless steel [J]. Oxid. Met., 2001, 56(3): 231-250[3] Kofstad P, High Temperature Corrosion [M]. London/New York: Elsevier Applied Science, 1988[4] Saunders S R J, Monteiro M, Rizzo F. The oxidation behavior of metals and alloys at high temperatures in atmospheres containing water vapour: A review [J]. Prog. Mater. Sci., 2008, 53:775-837[5] Sebastien F, Sebastien C, Gilles C. Metallic interconnects for solid oxide fuel cell: Effect of water vapour on oxidation resistance of differently coated alloys [J]. J. Power Sources, 2009, 193: 136-145[6] Larring Y, Haugsrud R, Norby T. H T. corrosion of Cr-5wt%Fe-1wt% Y2O3 alloy and conductivity of the oxide scale-effects of water vapor[J]. J. Electrochem. Soc., 2003, 150:374-379[7] Quadakkers W J, Zurek J, Hansel M. Effect of water vapour on high temperature oxidation of FeCr alloys [J]. JOM, 2009, 61(7):44-50[8] Prescott R, Graham M J. The formation of aluminum oxide scales on high-temperature alloys [J]. Oxid. Met., 1992, 38(3-4):233-254[9] Smialek J L, Robinson R C, Opila E J, et al. SiC and Si3N4 recession due to SiO2 scale volatility under combustor conditions [J]. Adv. Compos. Mater, 1999, 8(1): 33-45[10] Zhou C G, Yu J S, Gong S K, et al. Influence of water vapor on the isothermal oxidation behavior of low pressure plasma sprayed NiCrAlY coating at high temperature [J]. Surf. Coat.Technol., 2002, 161: 86-91[11] Al-Badairy H, Tatlock G J. The influence of moisture content of the atmosphere on alumina scale formation and growth during high temperature oxidation of PM2000 [J]. Mater. High Temp.,2000, (17): 133-137[12] Simms N J, Norton J F, Encinas-Oropesa A, et al. An evaluation of the performance of candidate gas turbine abradeable seal materials exposed to a high temperature combustion atmosphere [J]. Mater. Sci. Forum, 2004, 461-464: 875-882[13] Chevalier S, Juzon1 P, Przybylski K, et al. Water vapor effect on high-temperature oxidation behavior of Fe3Al intermetallics[J]. Sci. Technol. Adv. Mat., 2009, (10): 7-12[14] Canovic S, Engkvist J, Liu F, et al. Microstructural investigation of the initial oxidation of the FeCrAlRE alloy Kanthal AF in dry and wet O2 at 600 and 800℃[J]. J. Electrochem. Soc.,2010, 157(6): 223-230[15] Kvernes I, Oliveira M, Kofstad P. High temperature oxidation of Fe-13Cr-xAl alloys in air/water vapor mixtures [J].Corros. Sci., 1977, 17: 237-52[16] Cheng S Y, Kuan S, Tsai W. Effect of water vapor on annealing scale formation on 316SS [J]. Corros. Sci., 2006, 48(3):634-649[17] Janakiraman R, Meier G H, Pettit F S. The effect of water vapour on the oxidation of alloys that develop alumina scales for protection[A].Tri-Service Conference on Corrosion, Proceedings [C].Wrightsville Beach: N.C, 1997. 1-15[18] Molins R, Huntz A M. Recent improvements in the understanding of alumina film formation and durability [J]. Mater.Sci. Forum, 2004, 461-464: 29-36[19] Liu F, Josefsson H, Svensson J E, et al. Cyclic oxidation of two FeCrAIRE foils at 1100 deg C-The influence of the concentration of minor alloying elements on scale [J]. Mater. Sci.Forum, 2008, 595-598 (part 2): 707-716[20] Pijolat M, Dauzat M, Soustelle M. Influence of additives and water vapour on the transformation of transition aluminas into alpha alumina [J]. Thermochim. Acta, 1987, 122(1): 71-77[21] Gotlind H, Liu F, Svensson J E, et al. The effect of water vapor on the initial stages of oxidation of the FeCrAl alloy Kanthal AF at 900℃[J]. Oxid. Met., 2007, 67: 251-266[22] Opila E J, Myers D L. Alumina volatility in water vapor at elevated temperatures [J]. J. Am. Ceram. Soc., 2004, 87: 1701-1705[23] Opila E J, Jacobson N S, Myers D L, et al. Predicting oxide stability in high-temperature water vapor [J]. JOM, 2006, 1:22-28[24] Bansal N P, Zhu D. Thermal conductivity of zirconia alumina composites [J]. Ceram. Int., 2005, 31: 911-916[25] Krikorian O H. Thermochemical hydrogen production studies at LLNL: a status report[A]. International Energy Agency Annex 1 Workshop on Thermochemical Hydrogen[C]. United States: High Temp High Press, 1982. 1-7[26] John Y. High temperature oxidation and corrosion of metals, Chapter 10: Effects of water vapour on oxidation, Corrosion Series [J], 2008, 1: 455-495[27] Douglass D L, Kofstad P, Rahmel A, et al. International workshop on high temperature oxidation-subject area 1: the role of water vapour in the oxidation of metals and alloys[J]. Oxid. Met.,1996, 45(5/6): 529-620[28] Buscail H, Heinze S, Dufour Ph, et al. Water-vapor-effect on the oxidation of Fe 21.5 wt.% Cr, 5.6 wt.% Al at 1000℃[J]. Oxid.Met., 1997, 47(5-6): 445-64[29] Pint B A, Haynes J A, Zhang Y, et al. The effect of water vapor on the oxidation behavior of Ni-Pt-Al coatings and alloys [J].Surf. Coat. Technol., 2006, 201(7): 3852-3856[30] Leyens C, Fritscher K, Gehrling R, et al. Oxide scale formation on a MCrAlY coating in various H2-H2O atmospheres[J]. Surf. Coat. Technol., 1996, 82: 133-144[31] Gunnar H, Tveten B, Hornlund E. Hydrogen in chromium: influence on the high-temperature oxidation kinetics in H2O, oxide-growth mechanisms, and scale adherence [J]. Oxid.Met., 2000, 54(1-2): 1-10[32] Henry S, Mougin J, Wouters Y, et al. Characterization of chromia scales grown on pure chromium in different oxidizing atmospheres [J]. Mater. High Temp., 2000, 17: 231-4[33] Hudson L K, Misra C, Perrotta A J, et al. Aluminium Oxide[A]. In Ullmann's Encyclopedia of Industrial Chemistry [C]. New York: Wiley-VCH Verlag, 2002[34] Janakiraman R, Meier G H, Pettit F S. The effect of water vapour on the oxidation of alloys that develop alumina scales for protection[A]. Cyclic oxidation of high temperature materials-mechanisms, testing methods, characterization and life time estimation [C]. European: European federation of corrosion publications, 1999. 27: 38-62[35] Maris-Sida M C, Meier G H, Pettit F S. Some water vapor effects during the oxidation of alloys that are α-Al2O3 formers [J]. Metall. Mater. Trans., 2003,34A: 2609-2619[36] Brady M P, Yamamoto Y, Santella Ml, et al. Composition, microstructure, and water vapor effects on internal/external oxidation of alumina-forming austenitic stainless steels[J]. Oxid.Met., 2009, 72(5-6): 311-333[37] Onal K, Maris-Sida M C, Meier G H, et al. Water vapor effects on the cyclic oxidation resistance of alumina forming alloys [J]. Mater. High Temp., 2003, 20: 81-91[38] Janakiraman R, Meier G H, Pettit F S. The effect of water vapor on the oxidation of alloys that develop alumina scales for protection [J]. Metall. Mater. Trans., 1999, 30A: 2905-13[39] Smialek J L, Morscher G N. Delayed alumina scale spallation on Rene'N5+Y: moisture elects and acoustic emission [J].Mater. Sci. Eng., 2002, 332A: 11-24[40] Tallman R L, Gulbransen E A. Crystal morphology and mechanisms of growth of α-Fe (III) oxide whiskers on iron [J]. J. Electrochem. Soc., 1967, 114(12): 1227-1230[41] RuDiger D. Solution and transport of water in oxides [J]. Mater. High Temp., 2005, 22: 93-103[42] Raynaud G M, Rapp R A. In situ observation of whiskers, pyramids and pits during the high-temperature oxidation of metals [J]. Oxid. Met., 1984, 21: 89-102[43] Huntz A M, Hou P Y, Molins R. Study by deflection of the oxygen pressure influence on the phase transformation in alumina thin films formed by oxidation of Fe3Al [J]. Mater. Sci. Eng.,2007, 467A (1-2): 59-70[44] Engkvist J, Canovic S, Hellstrom K, et al. Alumina scale formation on a powder metallurgical FeCrAl alloy (Kanthal APMT) at 900-1100℃ in dry O2 and in O2+H2O [J].Oxid. Met., 2010, 73: 233-253 |
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