Access the full text.
Sign up today, get DeepDyve free for 14 days.
D. Matlock, G. Krauss, J. Speer (2005)
New Microalloyed Steel Applications for the Automotive SectorMaterials Science Forum, 500-501
O. Bouaziz, H. Zurob, Mingxin Huang (2013)
Driving Force and Logic of Development of Advanced High Strength Steels for Automotive Applicationssteel research international, 84
M. Gómez, A. Quispe, S. Medina (2014)
Influence of the Microalloying Elements on the Temporary Inhibition of Static Recrystallization by Strain‐Induced Precipitatessteel research international, 85
J. Cahn (1962)
The Impurity‐Drag Effect in Grain Boundary MotionActa Metallurgica, 10
W. Bleck, Kriangyut Phiu-on (2009)
Effects of Microalloying in Multi Phase Steels for Car Body Manufacture
S. Vervynckt, K. Verbeken, P. Thibaux, Y. Houbaert (2011)
Recrystallization–precipitation interaction during austenite hot deformation of a Nb microalloyed steelMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 528
(2011)
Mater
C. Philippot, J. Drillet, P. Maugis, V. Hébert, M. Dumont (2014)
Austenite formation in a ferrite/martensite cold-rolled microstructure during annealing of advanced high-strength steelsRevue De Metallurgie-cahiers D Informations Techniques, 111
J. Speer, S. Hansen (1989)
Austenite recrystallization and carbonitride precipitation in niobium microalloyed steelsMetallurgical Transactions A, 20
Sarah Kiyanrad, Julia Lougovaya, A. Sarri, Kai Trampedach (1897)
Metall
M. Akben, I. Weiss, J. Jonas (1981)
Dynamic precipitation and solute hardening in A V microalloyed steel and two Nb steels containing high levels of MnActa Metallurgica, 29
A. Deschamps, Y. Bréchet (1998)
Influence of predeformation and agEing of an Al–Zn–Mg alloy—II. Modeling of precipitation kinetics and yield stressActa Materialia, 47
C. Bos, M. Mecozzi, J. Sietsma (2010)
A microstructure model for recrystallisation and phase transformation during the dual-phase steel annealing cycleComputational Materials Science, 48
H. Zurob, Y. Bréchet, G. Purdy (2001)
A model for the competition of precipitation and recrystallization in deformed austeniteActa Materialia, 49
Christian Smith (1948)
Grains, phases, and interfaces:An introduction of microstructure, 175
Aaas News, E. Lu, Min-Min Zhou, Rong Mocsai, A. Myers, E. Huang, B. Jackson, Davide Ferrari, V. Tybulewicz, V. Lowell, Clifford Lepore, J. Koretzky, Gary Kahn, M. L., F. Achard, H. Eva, Ernst-Detlef Schulze, J. Acharya, U. Acharya, U. Acharya, Shetal Patel, E. Koundakjian, K. Nagashima, Xianlin Han, J. Acharya, D. Adams, Jonathan Horton, Blood, M. Adams, M. McVey, J. Sekelsky, J. Adamson, G. Kochendoerfer, A. Adeleke, A. Kamdem-Toham, Alan Aderem, C. Picard, Aeschlimann, G. Haug, G. Agarwal, M. Scully, H. Aguilaniu, L. Gustafsson, M. Rigoulet, T. Nyström, Asymmetric Inheri, Ferhaan Ahmad, J. Schmitt, M. Aida, S. Ammal, J. Aizenberg, D. Muller, J. Grazul, D. Hamann, J. Ajioka, C. Su, A. Akella, M. Alam, F. Gao, A. Alatas, H. Sinn, Titus Albu, P. Zuev, M. Al-Dayeh, J. Dwyer, A. Al-ghonaium, Sami Al-Hajjar, S. Al-Jumaah, A. Allakhverdov, V. Pokrovsky, Allen, A. Brown, James Allen, A. Brown, James Gillooly, James (1893)
Book ReviewsBuffalo Medical and Surgical Journal, 33
D. Yang, E. Brown, D. Matlock, G. Krauss (1985)
Ferrite recrystallization and austenite formation in cold-rolled intercritically annealed steelMetallurgical Transactions A, 16
M. Hillert, B. Sundman (1976)
A treatment of the solute drag on moving grain boundaries and phase interfaces in binary alloysActa Metallurgica, 24
B. Pereda, A. Fernandez, B. López, J. Rodríguez-Ibabe (2007)
Effect of Mo on Dynamic Recrystallization Behavior of Nb–Mo Microalloyed SteelsIsij International, 47
H. Zurob, C. Hutchinson, Y. Bréchet, G. Purdy (2002)
Modeling recrystallization of microalloyed austenite: effect of coupling recovery, precipitation and recrystallizationActa Materialia, 50
J. Huang, W. Poole, M. Militzer (2004)
Austenite formation during intercritical annealingMetallurgical and Materials Transactions A, 35
(2014)
Steel Res
A. Haldar, S. Suwas, D. Bhattacharjee (2009)
Microstructure and Texture in Steels
R. Song, N. Fonstein, H. Jun, N. Pottore, D. Bhattacharya, S. Jansto (2014)
Effects of Nb on Microstructural Evolution and Mechanical Properties of Low-Carbon Cold-Rolled Dual-Phase SteelsMetallography, Microstructure, and Analysis, 3
F. Humphreys, M. Hatherly (1995)
Recrystallization and Related Annealing Phenomena
C. Capdevila, T. Cock, C. García-Mateo, F. Caballero, C. Andrés (2005)
Influence of Second Phase Particles on Recrystallisation of Cold-Rolled Low Carbon Microalloyed Steels during Isothermal AnnealingMaterials Science Forum, 500-501
C. Sinclair, C. Hutchinson, Y. Bréchet (2007)
The Effect of Nb on the Recrystallization and Grain Growth of Ultra-High-Purity α-Fe: A Combinatorial ApproachMetallurgical and Materials Transactions A, 38
M. Gouné, P. Maugis, F. Danoix (2015)
Nucleation and growth of carbo-nitride nanoparticles in α-Fe-based alloys and associated interfacial processNanotechnology Reviews, 4
A. Chbihi, D. Barbier, L. Germain, A. Hazotte, M. Gouné (2014)
Interactions between ferrite recrystallization and austenite formation in high-strength steelsJournal of Materials Science, 49
H. Andrade, M. Akben, J. Jonas (1983)
Effect of molybdenum, niobium, and vanadium on static recovery and recrystallization and on solute strengthening in microalloyed steelsMetallurgical Transactions A, 14
C. Hutchinson, H. Zurob, C. Sinclair, Y. Bréchet (2008)
The comparative effectiveness of Nb solute and NbC precipitates at impeding grain-boundary motion in Nb steelsScripta Materialia, 59
D. Muljono, M. Ferry, D. Dunne (2001)
Influence of heating rate on anisothermal recrystallization in low and ultra-low carbon steelsMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 303
S. Medina, C. Hernández (1996)
Modelling of the dynamic recrystallization of austenite in low alloy and microalloyed steelsActa Materialia, 44
(2010)
Comput
Adjusting ferrite recrystallization kinetics during annealing is a way to control the final microstructure and thus the mechanical properties of advanced cold-rolled high-strength steels. Two strategies are commonly used for this purpose: adjusting heating rates and/or adding microalloying elements. The present work investigates the effect of heating rate and microalloying elements Ti, Nb, and Mo on recrystallization kinetics during annealing in various cold-rolled Dual-Phase steel grades. The use of combined experimental and modeling approaches allows a deeper understanding of the separate influence of heating rate and the addition of microalloying elements. The comparative effect of Ti, Nb, and Mo as solute elements and as precipitates on ferrite recrystallization is also clarified. It is shown that solute drag has the largest delaying effect on recrystallization in the present case and that the order of solute drag effectiveness of microalloying elements is Nb > Mo > Ti.
Metallurgical and Materials Transactions A – Springer Journals
Published: May 4, 2018
Access the full text.
Sign up today, get DeepDyve free for 14 days.