Stacking fault energy of cryogenic austenitic steels

Stacking fault energy and stacking fault nucleation energy are defined in terms of the physical nature of stacking faults and stacking fault energy, and the measuring basis for stacking fault energy. Large quantities of experimental results are processed with the aid of a computer and an expression for calculating stacking fault energy has been obtained as γ³⁰⁰_SF(mJ·m^-2)=γ⁰_SF+1.59Ni-1.34Mn+0.06Mn²-1.75Cr+0.01Cr²+15.21Mo-5.59Si-60.69(C+1.2N)^1/2 + 26.27(C+1.2N)(Cr+Mn+Mo)^1/2+0.61[Ni·(Cr+Mn)]^1/2.     

新型牙齿正畸丝材料在唾液中的往复滑动摩擦磨损特性研究

采用小振幅往复滑动摩擦磨损试验机评价了新型牙齿正畸丝材料13Cr24Mn0.44N不锈钢在水和唾液中的摩擦磨损行为,并探讨其磨损机理.结果表明:在唾液中活性成分的作用下,试样表面生成了软质易剪切的表面膜,使得摩擦系数降低,同时部分残留于磨痕中的磨屑在水或唾液介质润滑下承担了类似滚动轴承中"滚珠"的角色,进一步降低了摩擦系数;在2种介质中磨痕深度均随载荷增大而增加,但在唾液中的磨痕深度均小于在水中的磨痕深度,磨损和腐蚀之间呈现"负交互"作用;不锈钢在水中的磨痕呈现微切削和犁沟机制,在唾液中小载荷下的磨痕与水中相似,磨痕呈现微切削和犁沟机制,但在较大载荷时的磨损机制为疲劳脱层并伴有显微切削.