Effect of Heat Treatment on the Precipitation Behavior and Hardness of the Second Phase of 0Cr21Mn17Mo3N0.8 High Nitrogen Alloys

The effects of different heat treatment processes on the morphology, quantity and size of the precipitated nitrides phase of 0Cr21Mn17Mo3N0.8 high nitrogen alloy were studied. The microstructure of the alloy was observed and characterized by metallographic microscope, transmission electron microscop...

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Bibliographic Details
Published inMaterials science forum Vol. 944; pp. 373 - 377
Main Authors Xu, Yun Xiu, Chen, Zi Wei, Huang, Yan, Yang, You
Format Journal Article
LanguageEnglish
Published Pfaffikon Trans Tech Publications Ltd 01.01.2019
Subjects
Alloy steels
Alloys
Chromium nitride
Cooling
Deposition
Hardness
Heat treating
Heat treatment
Morphology
Nitrogen
Preservation
Spheroidizing
Surface layers
Water quenching
Heat Treatment
High Nitrogen Alloy
Hardness
Nitride Precipitation
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Summary:The effects of different heat treatment processes on the morphology, quantity and size of the precipitated nitrides phase of 0Cr21Mn17Mo3N0.8 high nitrogen alloy were studied. The microstructure of the alloy was observed and characterized by metallographic microscope, transmission electron microscope, etc. And the hardness of high nitrogen alloy under different treatment processes were tested. The results showed that sample alloy was cooling in the furnace after heat preservation of 1140°C for 8h. Lamellar nitride is precipitated from the alloy, its composition is Cr2N, its size is about 50-100nm, and the precipitation process mainly occurs 1-2mm below the surface layer. This can make the alloys to form surface-reinforced composites. Meanwhile, the hardness of the alloy has increased significantly from 29.3HRC to 61.3HRC, because of the precipitation of the second phase. The high nitrogen alloys after slow cooling treatment were treated with spheroidization at the temperature lower than that of the complete austenitizing, and the layered deposition began fusing at 950°C. Under the temperature of 1120°C heat preservation for 8h, then water quenching, slice layer deposition completely dissolved into granule, and the particle size is about 20nm to 50nm, the alloy of hardness after spheroidizing has decreased to 48.3HRC.
Bibliography:Selected, peer reviewed papers from the Chinese Materials Conference 2018 (CMC 2018), July 12-16, 2018, Xiamen City, Fujian, China
ISSN:0255-5476
1662-9752
1662-9752
DOI:10.4028/www.scientific.net/MSF.944.373