陈平虎等：高钒耐磨合金在不同冷却方式下的高温氧化行为 ·91· 参考文献 2016,114:1 [1]Moskalyk RR,Alfantazi A M.Processing of vanadium:a review. [10]Li D S,Dai Q X,Cheng X N,et al.High-temperature oxidation Miner Eng,2003,16(9):793 resistance of austenitic stainless steel Crl8Nil 1Cu3Al3 MnNb.J [2]Lee DG,Lee K,Lee S.Effects of tempering on microstructure, Iron Steel Res Int,2012,19(5):74 hardness,and fracture toughness of VC/steel surface composite [11]Li R,Zhou Z,He D Y,et al.Microstructure and high-tempera- fabricated by high-energy electron beam irradiation.Surf Coat ture oxidation behavior of wire-arc sprayed Fe-based coatings. Technol..2006,201(34):1296 Surf Coat Technol,2014,251:186 [3]Zhao W M,Liu Z X,Ju Z L,et al.Effects of vanadium and rare- [12]Kriiger M.High temperature compression strength and oxidation earth on carbides and properties of high chromium cast iron.Mater of a V-9Si-13B alloy.Scripta Mater,2016,121:75 Sci Forum,2008,575-578:1414 [13]Luo XX,Yao Z J,Zhang P Z,et al.A study on high tempera- [4]Ye F X,Hojamberdiev M,Xu Y H,et al.Fe,Cr)C:/Fe sur- ture oxidation behavior of double glow plasma surface metallurgy face gradient composite:microstructure,microhardness,and wear Fe-Al-Cr alloyed layer on Q235 steel.Appl Suf Sci,2014. resistance.Mater Chem Phys,2014,147(3):823 305:259 [5]Zhuo W B.Jiang G A,Chen Y C.A powder chromizing process [14]Chattopadhyay B,Wood G C.The transient oxidation of alloys with the advantage of direct quenching.J Mater Sci Eng,2004, 0 xid Met,1970,2(4):373 36(2):111 [15]Huntz A M,Schiitze M.Stresses generated during oxidation se- (卓文彬，江國安，陳永傅.可直接淬火之固體粉末滲鉻法 quences and high temperature fracture.Mater High Temp,1994, 材料科學與工程，2004,36(2)：111) 12(2-3):151 [6]Brady M P,Yamamoto Y,Santella M L,et al.Effects of minor [16]Yang F,Liu B,Fang D N.Analysis on high-temperature oxida- alloy additions and oxidation temperature on protective alumina tion and growth stress of iron-based alloy using phase field meth- scale formation in creep-resistant austenitic stainless steels.Scripta od.Appl Math Mech,2011,32(6):757 Mater,2007,57(12):1117 [17]Panicaud B.Grosseau-Poussard JL,Dinhut JF.On the growth [7]Kusumoto K,Shimizu K,Yaer X,et al.High erosion-oxidation strain origin and stress evolution prediction during oxidation of performance of Fe-based Nb or V containing multi-component al- metals.Appl Suf Sci,2006,252(16):5700 loys with Co addition at 1173 K.Mater Des,2015,88:366 [18]Chen J W,Jiang Z,Mu H,et al.Simulation on the thermal [8]Gao P H,Cao S T,Li J P,et al.High temperature oxidation re- stress of super304H oxidation scale at 600 C.Adr Mater Res, sistance of M42C stainless steel coatings deposited on the surface of 2015,.1065-1069:1934 cast iron through atmospheric plasma spraying.J Alloys Compd, [19]Ren C,He Y D,Wang D R.Fabrication and characteristics of 2016,684:188 YSZ-YSZ/Al,O:double-layer TBC.Oxid Met,2011,75(5-6): [9]Abe F.Kutsumi H,Haruyama H,et al.Improvement of oxidation 325 resistance of9 mass%chromium steel for advanced-ultra supercrit- [20]Xu C H,Gao W.Pilling-bedworth ratio for oxidation of alloys ical power plant boilers by pre-oxidation treatment.Corros Sci, Mater Res Innovations,2000,3(4):231陈平虎等: 高钒耐磨合金在不同冷却方式下的高温氧化行为 参 考 文 献 [1] Moskalyk R R, Alfantazi A M. Processing of vanadium: a review. Miner Eng, 2003, 16(9): 793 [2] Lee D G, Lee K, Lee S. Effects of tempering on microstructure, hardness, and fracture toughness of VC/ steel surface composite fabricated by high鄄energy electron beam irradiation. Surf Coat Technol, 2006, 201(3鄄4): 1296 [3] Zhao W M, Liu Z X, Ju Z L, et al. Effects of vanadium and rare鄄 earth on carbides and properties of high chromium cast iron. Mater Sci Forum, 2008, 575鄄578: 1414 [4] Ye F X, Hojamberdiev M, Xu Y H, et al. (Fe,Cr)7C3 / Fe sur鄄 face gradient composite: microstructure, microhardness, and wear resistance. Mater Chem Phys, 2014, 147(3): 823 [5] Zhuo W B, Jiang G A, Chen Y C. A powder chromizing process with the advantage of direct quenching. J Mater Sci Eng, 2004, 36(2): 111 (卓文彬, 江國安, 陳永傳. 可直接淬火之固體粉末滲鉻法. 材料科學與工程, 2004, 36(2): 111) [6] Brady M P, Yamamoto Y, Santella M L, et al. Effects of minor alloy additions and oxidation temperature on protective alumina scale formation in creep鄄resistant austenitic stainless steels. Scripta Mater, 2007, 57(12): 1117 [7] Kusumoto K, Shimizu K, Yaer X, et al. High erosion鄄oxidation performance of Fe鄄based Nb or V containing multi鄄component al鄄 loys with Co addition at 1173 K. Mater Des, 2015, 88: 366 [8] Gao P H, Cao S T, Li J P, et al. High temperature oxidation re鄄 sistance of M42C stainless steel coatings deposited on the surface of cast iron through atmospheric plasma spraying. J Alloys Compd, 2016, 684: 188 [9] Abe F, Kutsumi H, Haruyama H, et al. Improvement of oxidation resistance of 9 mass% chromium steel for advanced鄄ultra supercrit鄄 ical power plant boilers by pre鄄oxidation treatment. Corros Sci, 2016, 114: 1 [10] Li D S, Dai Q X, Cheng X N, et al. High鄄temperature oxidation resistance of austenitic stainless steel Crl8Nil 1Cu3Al3MnNb. J Iron Steel Res Int, 2012, 19(5): 74 [11] Li R, Zhou Z, He D Y, et al. Microstructure and high鄄tempera鄄 ture oxidation behavior of wire鄄arc sprayed Fe鄄based coatings. Surf Coat Technol, 2014, 251: 186 [12] Kr俟ger M. High temperature compression strength and oxidation of a V鄄鄄9Si鄄鄄13B alloy. Scripta Mater, 2016, 121: 75 [13] Luo X X, Yao Z J, Zhang P Z, et al. A study on high tempera鄄 ture oxidation behavior of double glow plasma surface metallurgy Fe鄄鄄Al鄄鄄 Cr alloyed layer on Q235 steel. Appl Surf Sci, 2014, 305: 259 [14] Chattopadhyay B, Wood G C. The transient oxidation of alloys. Oxid Met, 1970, 2(4): 373 [15] Huntz A M, Sch俟tze M. Stresses generated during oxidation se鄄 quences and high temperature fracture. Mater High Temp, 1994, 12(2鄄3): 151 [16] Yang F, Liu B, Fang D N. Analysis on high鄄temperature oxida鄄 tion and growth stress of iron鄄based alloy using phase field meth鄄 od. Appl Math Mech, 2011, 32(6): 757 [17] Panicaud B, Grosseau鄄Poussard J L, Dinhut J F. On the growth strain origin and stress evolution prediction during oxidation of metals. Appl Surf Sci, 2006, 252(16): 5700 [18] Chen J W, Jiang Z, Mu H, et al. Simulation on the thermal stress of super304H oxidation scale at 600 益 . Adv Mater Res, 2015, 1065鄄1069: 1934 [19] Ren C, He Y D, Wang D R. Fabrication and characteristics of YSZ鄄鄄YSZ / Al2O3 double鄄layer TBC. Oxid Met, 2011, 75(5鄄6): 325 [20] Xu C H, Gao W. Pilling鄄bedworth ratio for oxidation of alloys. Mater Res Innovations, 2000, 3(4): 231 ·91·