Dynamic recrystallization and precipitation in low carbon low alloy steel 26NiCrMoV 14-5

Hot working behavior of 26NiCrMoV 14-5 steel was investigated by performing hot compression testing at a temperature range of 850–1150°C and strain rates of 0.001–1s−1. The obtained flow curves at temperatures higher than 1000°C were typical of dynamic recrystallization, whereas at lower temperature...

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Bibliographic Details
Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2012-08, Vol.551, p.25-31
Main Authors: Mirzaee, Masoud, Keshmiri, Hamid, Ebrahimi, Golam Reza, Momeni, Amir
Format: Article
Language:English
Subjects:
Applied sciences
Cold working, work hardening
annealing, quenching, tempering, recovery, and recrystallization
textures
Cross-disciplinary physics: materials science
rheology
Elasticity. Plasticity
Exact sciences and technology
Flow curve
Hot compression
Hot deformation
Materials science
Mechanical properties and methods of testing. Rheology. Fracture mechanics. Tribology
Metals. Metallurgy
Phase diagrams and microstructures developed by solidification and solid-solid phase transformations
Physics
Precipitation
Strain induced precipitation
Treatment of materials and its effects on microstructure and properties
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Summary:Hot working behavior of 26NiCrMoV 14-5 steel was investigated by performing hot compression testing at a temperature range of 850–1150°C and strain rates of 0.001–1s−1. The obtained flow curves at temperatures higher than 1000°C were typical of dynamic recrystallization, whereas at lower temperatures the flow curves were representing work hardening without any indication of dynamic recrystallization. The apparent activation energy of the material was determined as 437kJ/mol and the flow stress was correlated to strain rate and temperature using the hyperbolic sine function. The flow curves at high temperatures were successfully modeled using a combination of the Cingara and Avrami equations. However, at temperatures below 1000°C, the predicted flow curves using the Cingara and Avrami equations were considerably different from the experimental curves. From the low work hardening rates and the increasing of flow stress at temperatures below 1000°C the possibility of dynamic precipitation could be elucidated. This idea was corroborated by observing the different dependence of flow stress on temperature at low and high temperatures. In order to assess the potential of precipitation in the material stress relaxation tests were performed at low and high temperatures and the results confirmed the possibility of dynamic precipitation at temperatures below 1000°C.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2012.04.063