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从超临界和超超临界汽轮机耐热钢的发展、组织结构、强化机理、性能、热处理和应用等方面阐述了该耐热钢的研究、发展和应用等方面的概况和发展趋势.指出了超超临界汽轮机耐热钢研究过程中存在的问题,结合未来超超临界汽轮机技术的发展,对超超临界汽轮机耐热钢的研究进行了展望.

参考文献

[1] Janos M. Beer .High efficiency electric power generation: The environmental role[J].Progress in energy and combustion science,2007(2):107-134.
[2] Schilling H D .75 Years of VGB:Power Plants 1970 to 1995 Energy Political Basic Conditions and Technical Developments[J].VGB Kraftwerkstechnik,1995,75(08):643-651.
[3] 张素心,阳虹,姚祖安.超临界汽轮机的开发与展望[J].上海汽轮机,2002(01):15-22.
[4] 苗金,危师让.超临界火电技术及其发展[J].热力发电,2002(05):2-5,15.
[5] 王为民,王建录.高效超临界汽轮机的研究与开发[J].动力工程,2004(05):609-613.
[6] 沈邱农,陈文辉.超超临界汽轮机的技术特点[J].动力工程,2002(02):1659-1663.
[7] Henry J F;Fishburn J D;Perrin I J.Advanced Supercritical Technology:Back to the Future[A].Ohio,USA:EPRI,2005:137-142.
[8] Kjaer S;Klauke F;Vanstone R et al.The Advanced Supercritical 700℃ Pulverised Coal-Fired Power Plant[J].VGB Power Technology,2002,82(07):46-49.
[9] 李荣夫.超临界汽轮机汽缸等铸钢件材料的选用[J].电站系统工程,2003(02):59-61.
[10] 邢春林,黄蓉,李振学.300MW、600MW汽轮机材料科研总结及汽轮机材料的研究方向[J].汽轮机技术,1997(03):179.
[11] Gregg J L.The Alloys of Iron and Molybdenum[M].New York,USA:McGraw-Hill,1932
[12] B/HJ 440-2004.B/HJ 440-2004.合金钢铸件技术条件[S].,2004.
[13] Mints I I;Khodykina L E;Shulgina N G .Creep Failure Characteristics of Heat-Resistant Cr-Mo-V Steels[J].Metal Science and Heat Treatment,1989,31(7-8):516-521.
[14] Tanoosaki K .Improvement of High Temperature Strength of 21/4Cr-1Mo Heat Resistant Steel[J].Tetsu To Hagane-Journal of the Iron & Steel Institute of Japan,1971,57(02):367-385.
[15] Bodnar R L;Ohhashi T;Jaffee R I .Effects of Mn,Si,and Purity on the Design of 3.5NiCrMoV,1CrMoV,and 2.25Cr-1Mo Bainitic Alloy Steels[J].Metallurgical and Materials Transactions,1989,20A(08):1445-1460.
[16] B/HJ 711-2002.B/HJ 711-2002.超临界汽轮机用ZG1Cr10MoVNbN不锈钢铸件技术条件[S].,2002.
[17] B/HJ 771-2006.B/HJ 771-2006.ZG1Cr10MoWVNbN钢汽轮机铸件技术条件[S].,2006.
[18] 胡平.超(超)临界火电机组锅炉材料的发展[J].电力建设,2005(06):26-29.
[19] 黄雅罗.超超临界火力发电技术及其应用前景[J].热力发电,2002(02):2-7,38.
[20] 毛雪平,王罡,马志勇.超超临界机组汽轮机材料发展状况[J].现代电力,2005(01):69-75.
[21] Fujimitsu MASUYAMA .History of Power Plants and Progress in Heat Resistant Steels[J].ISIJ International,2001(6):612-625.
[22] Scarlin B;Kern T U;Staubli M.The European Efforts in Material Development for 650℃ USC Power Plants-COST522[A].Ohio,USA:EPRI,2005:80-99.
[23] Fujita T .Current Progress in Advanced High Cr Ferritic Steels for High-Temperature Applications[J].ISIJ International,1992,32(02):175-181.
[24] Grobner P J;Hagel W C .The Effect of Molybdenum on High-Temperature Properties of 9 Pct Cr Steels[J].Metallurgical and Materials Transactions,1980,11A(04):633-642.
[25] LIU Xing-yang;Fujita T .Effect of W Content on Creep Rupture Strength and Toughness of a 12% Cr Heat Resisting Steel[J].Transactions of the Iron and Steel Institute of Japan,1987,27(11):287-298.
[26] LIU Xing-yang;Fujita T .Effects of Mo and W Contents on Creep Rupture Strength and Toughness of a 10% Cr Heat Resistant Steel[J].Journal of the Iron & Steel Institute of Japan,1988,74(03):513-520.
[27] LIU Xing-yang;Fujita T .Effect of Chromium Content on Creep Rupture Properties of a High Chromium Ferritic Heat Resisting Steel[J].ISIJ International,1989,29(08):680-686.
[28] Hanus R.Advanced 9-12%Cr Cast Steel Grades,Research Foundry Process Development-Quality-Experience[A].Ohio,USA:EPRI,2005:638-651.
[29] M.H?ttestrand;H.-O.Andrén .boron distribution in 9-12% chromium steels[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,1999(1):33-37.
[30] Kloos K H;Granacher J;Oehl M .Creep Behaviour of Heat Resistant Steels.Part Ⅱ:Creep Equations for Steels 2.25Cr-1Mo[J].Materialwissenschaft Und Werkstofftechnik,1993,24(09):331-338.
[31] Keisuke Yamamoto;Yoshisato Kimura;Yoshinao Mishima .Effect of matrix micro structure on precipitation of Laves phase In Fe-10Cr-1.4W(-Co) alloys[J].Intermetallics,2006(5):515-520.
[32] Knezevic V;Sauthoff G.Improvement of Creep Strength of Heat-Resistant Martensitic/Ferritic 12%Cr Steels[A].Ohio,USA:EPRI,2005:1256-1269.
[33] Fujita T .Heat-Resistant Steels for Aadvanced Power Plants[J].Current Advances in Materials and Processes,1992,141(04):42-45.
[34] Berger C;Mayer K H;Scarlin R B .Neue Turbinenstaehle zur Verbesserung der Wirtschaftlichkeit yon Kraftwerken(New Turbine Steels for the Improvement of Power Station Economy)[J].VGB Kraftwerkstechnik,1991,71(07):686-699.
[35] Kawabe Y;Nakagawa R;Mukoyama T .Creep Rupture Strength of 18Cr-12Ni-3Mo Austenitic Heat Resisting Steel Containing Nitrogen[J].Transactions of National Research Institute For Metals,1971,13(03):110-123.
[36] Miyashita K.Overview of Advanced Steam Plant Development in Japan[M].London,1997:17-30.
[37] Blum R;Hald J.High Efficiency USC Power Plant-Present Status and Future Potential[A].Stockholm,Sweden:CEC,1998:13-28.
[38] Vanstone R.Advanced 700℃ Pulverized Fuel Power Plant[A].London:IOM Communications Ltd,2000:91-97.
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