分别采用Al2O3与Y2O3为壳型面层材料,离心铸造了Ti46Al1B(原子分数,%)合金阀门铸件,通过SEM,XRD以及气体分析等方法,确定壳型内表面物相组成、铸件与壳型反应层厚度以及合金的进氧情况,分析了壳型材料与Ti46Al1B合金的反应机理.结果表明,Y203和A120s壳型与合金的反应层厚度分别约为90和170 pm,使用Y203壳型时铸件进氧少,其热力学稳定性好于Al2O3壳型,与热力学计算结果相符.Y2O3壳型比Al2O3壳型更适合铸造Ti46Al1B阀门.
参考文献
| [1] | Kim Y W.Mater Sci En9,1995; A192-193:519 |
| [2] | Kim Y W.Acta Metall,1999; 12:334 |
| [3] | Loretto M H,Horspool D,Botten R,Hu D,Li Y G,Srivns-tava D,Sharman R,Wu X.Mater Sci Eng,2002; A329-331:1 |
| [4] | Yamaguchi M,Inui H.In:Daloria R,Lewwandowski J J,Liu C T,Martin P L,Miracle D B,Nathal M V,eds.,Structural Intermetallics,Warrendale:TMS,1993:127 |
| [5] | Lapin J,Nazmy M.Mater Sci Eng,2004; A380:298 |
| [6] | Klaus G.Intermetallics,2006; 14:355 |
| [7] | Liu K,Ma Y C,Gao M,Rao G B,Li Y Y,Wei K,Wu X H,Loretto M H.Intermetallics,2005; 13:925 |
| [8] | Blum M,Jarczyk G,Schoh H,Pleier S,Busse P,Lau-denberg H J,Segtrop K,Simon R.Mater Sci Eng,2002; A329-331:616 |
| [9] | Sommer A W,Keijzers G C.In:Kim Y W,Clemens H,Rosenberger A H,eds.,Gamma Titanium Aluminides,Warrendale:TMS,2003:3 |
| [10] | Jia Q,Cui Y Y,Yang R.Acta Metall Sin,2002; 38:351 (贾清,崔玉友,杨锐.金属学报,2002;38:351) |
| [11] | Jia Q,Cui Y Y,Yang R.J Mater Sci,2006; 41:3045 |
| [12] | Jones S,Bentley S A,Marquis P M.Br Ceram Trans,2002; 101:100 |
| [13] | Nan H,Xie C M.Acta MetaU Sin,2002; 38:345 (南海,谢成木.金属学报,2002;38:345) |
| [14] | Yan C F,Zhao G J,Hang Y,Xu J.J Synth Cryst,2005; 34:144 (严成锋,赵广军,杭寅,徐军.人工晶体学报,2005;34:144) |
| [15] | Kobayashi Y,Tsukihashi F.High Temp Mater Processes,2000; 19:211 |
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