Abstract
The 25Cr2MoVA steel was subjected to various heat treatments. We found that the hardness increased when the quenching temperature was in the range of 870 – 910 °C, and then it decreased for the temperature of 910 – 990 °C. The maximum hardness was 553 HV after quenching from 910 °C. Following quenching from 910°C, the 25Cr2Mo-VA steel was tempered in the temperature range of 560 to 750 °C. With an increase in the tempering temperature, the hardness and tensile strength of the material decreased, while the impact toughness increased; the corrosion resistance increased initially and then decreased. The best heat treatment process for the 25Cr2MoVA steel involved quenching form 910 °C and tempering at 650°C for 1 h, the hardness was 362 HV, the tensile strength reached 1 310 MPa, the impact energy reached 149 J, and the material exhibited the best corrosion resistance.
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© 2021 Walter de Gruyter GmbH, Berlin/Boston, Germany
Artikel in diesem Heft
- Contents
- Original Contributions
- Predicting doped Fe-based superconductor critical temperature from structural and topological parameters using machine learning
- Preparation of ZnO nanoflakes and assessment of their removal of HCN, NO2 and SO2 toxic gases
- Performance analysis and comparison of methyl-modified Al2O3/SiO2 xerogels fabricated by two methods
- The effect of SiC nanoparticles and sintering temperature on the structural and wear properties of Cu–MWCNTs–SiC hybrid nanocomposites
- Synthesis and characterization of Co–B–Fe–Ti nanosized alloyed powders
- Characterization of H13 steel powder oxidation at different temperatures
- Diffusion-alloying sintering of Cr–Mo pre-alloyed iron powders with carbon: The effect of the carbon introduction method on the sinter’s properties
- The effect of structure and texture on pure magnesium properties
- Mechanism of kink band formation in zinc single crystals
- Microstructural and fractographic analysis of A359/Si3N4 surface composite produced by friction stir processing
- Effect of heat treatment on the microstructure and properties of 25Cr2MoVA petroleum casing steel
- Notifications
- Deutsche Gesellschaft für Materialkunde / German Materials Science Society
Artikel in diesem Heft
- Contents
- Original Contributions
- Predicting doped Fe-based superconductor critical temperature from structural and topological parameters using machine learning
- Preparation of ZnO nanoflakes and assessment of their removal of HCN, NO2 and SO2 toxic gases
- Performance analysis and comparison of methyl-modified Al2O3/SiO2 xerogels fabricated by two methods
- The effect of SiC nanoparticles and sintering temperature on the structural and wear properties of Cu–MWCNTs–SiC hybrid nanocomposites
- Synthesis and characterization of Co–B–Fe–Ti nanosized alloyed powders
- Characterization of H13 steel powder oxidation at different temperatures
- Diffusion-alloying sintering of Cr–Mo pre-alloyed iron powders with carbon: The effect of the carbon introduction method on the sinter’s properties
- The effect of structure and texture on pure magnesium properties
- Mechanism of kink band formation in zinc single crystals
- Microstructural and fractographic analysis of A359/Si3N4 surface composite produced by friction stir processing
- Effect of heat treatment on the microstructure and properties of 25Cr2MoVA petroleum casing steel
- Notifications
- Deutsche Gesellschaft für Materialkunde / German Materials Science Society