论文部分内容阅读
Solid solution nitriding technologies of 15Cr-7.5Mn-2.6Mo duplex stainless steel were investigated by using of orthogonal tests. The results show that the best technology would be the processes of 1050°C x 2h + 1150°C x 3h + 1050°C x 2h + 1150°C x 4h under pure N2 with PN2=0.15MPa. The high nitrogen austenitic case with the depth of 1.62mm can be obtained. Orthogonal tests show that the type of atmosphere has the most notable effect on solid solution nitriding process; the pressure in the furnace and the nitriding processes has a notable effect. X-ray diffraction analyses results indicate that the main phases in the cases of the solution-nitrided samples cooled in the furnace are high nitrogen austenite, CrN, Fe3O4 and nitrogen containing ferrite. In the other samples experienced solid solution nitriding and solution treatment the obtained phase in the cases is high nitrogen austenite only. The results show that solid solution nitriding is a process that nitrogen absolutely diffuses in the austenite. The diffusing activation energy in the conditions of PN2 = O.lSMPa and 1050°C ~ 1200°C is 186.6KJ/mol.
The results show that the best technology would be the processes of 1050 ° C x 2h + 1150 ° C x 3h + 1050 ° C x 2h + 1150 ° C x 4h under pure N2 with PN2 = 0.15MPa. Orthogonal tests show that the type of atmosphere has the most notable effect on solid solution nitriding process ; the pressure in the furnace and the nitriding processes has a not can effect. X-ray diffraction analyzes results indicate that the main phases in the cases of the solution-nitrided samples cooled in the furnace are high nitrogen austenite, CrN, Fe3O4 and nitrogen containing ferrite. In the other samples experienced solid solution nitriding and solution treatment the obtained phase in the cases is high nitrogen austenite only. The results show that solid solution nitriding is a process that nitrogen absolutely diffuse s in the austenite. The diffusing activation energy in the conditions of PN2 = O.lSMPa and 1050 ° C ~ 1200 ° C is 186.6KJ / mol.