1)  CASS
奥氏体不锈钢铸件
1.
In primary loop in nuclear plants,the Cast Austenite Stainless Steel(CASS) under operation temperature will face to the issue of thermal aging besides of irradiation damage.
在核电站一回路中,奥氏体不锈钢铸件(CASS)在运行温度下长期工作除了受到辐照损伤外,还将面临热老化问题。
2)  austenitic
奥氏体
1.
Surface Quality Control of Cold Rolled Austenitic Stainless Stell Strip for Deep Drawing;
冲压用冷轧奥氏体不锈钢带的表面质量控制
2.
Supersonic detection for welding joint of austenitic stainless steel small-diameter pipe;
奥氏体不锈钢小径管焊缝超声波检测
3.
Inspection detection research in austenitic stainless steel with different ultrasonic probes;
奥氏体不锈钢焊接接头超声波检测研究
3)  austenite steel
奥氏体钢
1.
The interface lattice misfitting theory can not explain that TiC and CaS act as an efficient catalyzer during the non-equilibrium solidification of austenite steel.
利用界面共格对应理论无法解释奥氏体钢非平衡凝固过程中TiC、CaS为奥氏体枝晶有效异质核心的现象。
2.
The performance of granular γ+(Fe,Mn)3C eutectics reinforced austenite steel matrix composites (EAMC) was studied, and the strengthening/toughness match and wear resistance were analyzed.
在研究团球γ+(Fe,Mn)3C共晶体增强奥氏体钢基自生复合材料(EAMC)的力学与耐磨性能的基础上,分析了EAMC的强韧化及耐磨机理。
3.
The effect of sliding velocity on the friction behaviors of in situ granular 7+(Fe, Mn)3C eutectics reinforced austenite steel matrix composites (EAMC) has been investigated by the pin-on disc dry sliding tests and scanning electron microscopy (SEM) observation.
利用MPX-2000型主轴盘销式磨损实验机和扫描电子显微镜(SEM)研究了相对滑动速度对团球γ+(Fe,Mn)_3C共晶体增强奥氏体钢基自生复合材料(EAMC)摩擦学性能的影响。
4)  austenite film
奥氏体膜
5)  austenizing
奥氏体化
1.
The quenching microstructure of low carbon steel after austenizing with and without DC electric field was studied.
研究了低碳钢在直流静电场中进行奥氏体化后淬火的显微组织。
2.
From the mechanics of steel austenizing ,a mathimatic model of austenizing process is set up.
从钢的奥氏体化机理入手,建立了加热奥氏体的数学模型;并对激光加热温度场和硬化带进行了估算。
3.
The microstructure of 45CrMoV steel after austenizing followed by air cooling and tempering at various temperatures have been studied, using TEM and SAD.
利用透射电镜和选区电子衍射研究了45CrMoV钢奥氏体化后空冷及其在不同温度回火的显微组织。
6)  austenitic steel
奥氏体钢
1.
The direct relationship between stacking fault energy and phase transformation driving force of austenitic steels and the effect of stacking fault energy and strain energy on the morphology of martensite are deduced.
导出了在奥氏体钢中相变驱动力与层错能的关系以及层错能和应变能对马氏体形态的影响规律。
2.
The effects of stacking fault energy and strength on phase transformation in cryogenic austenitic steels were studied.
研究了低温奥氏体钢中层错能和强度对相变的作用 ,导出了相变临界分切应力和层错能与强度之间的关系式。
参考词条
补充资料:奥氏体不锈钢
分子式:
CAS号:

性质:在常温下具有奥氏体组织的不锈钢。含铬18%和镍8%的不锈钢是最典型的奥氏体不锈钢,它常被称为18-8不锈钢。这种不锈钢在很宽的温度范围内都具有很高的强韧性,富于延展性,容易轧制和压缩等冷加工,它的耐蚀性和耐酸性,都优于铁素体不锈钢和马氏体不锈钢。添加钼和铜的镍铬系奥氏体不锈钢具有更好的耐蚀性和耐酸性,而且耐盐酸和卤化物腐蚀性也大为改善。除铬镍系奥氏体不锈钢之外,还有铬镍锰系以及不含镍和铬的铁锰铝系奥氏体不锈钢。由于奥氏体不锈钢具有全面、良好的综合性能,在工业上获得了广泛应用。

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