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1 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Processo Q&P (Quenching and Partitioning) Estudo de caso completo Fernando Rizzo
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2 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Projeto de Cooperação Internacional J.G. Speer, D.K. Matlock, A. Streicher – Colorado School of Mines, USA F. Rizzo, A. R. Aguiar – PUC, Rio de Janeiro, Brazil D.V. Edmonds, Kejian He – University of Leeds, UK NSF-CNPq (CIAM), NSF-EPSRC
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3 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Quenching and Partitioning : - Background - Fundamental Issues - Recent Results J.G. Speer, D.K. Matlock, B.C. De Cooman and J.G. Schroth, Acta Mater., 51 (2003) 2611- 2622. J.G. Speer, A.M. Streicher, D.K. Matlock, F.C. Rizzo and G. Krauss, Austenite Formation and Decomposition, ed. E.B. Damm and M. Merwin, TMS/ISS, Warrendale, PA, USA, 2003, pp. 505-522. John G. Speer, David V. Edmonds, Fernando C. Rizzo, David K. Matlock, Current Opinion in Solid-State and Materials Science, 8 (2004) 219-237
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4 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012
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5 The “Q&P” Process Quenching and Partitioning Provisional US Patent Application: September, 2003
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6 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 The “Q&P” Process Step 1.Austenitize or Intercritically Anneal - more austenite - lower C - higher M s - less austenite - higher C - lower M s
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7 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Step 2.Cool (quench?) below M s - M s -T Q controls martensite formation - intercritical annealing has more stable austenite and higher carbon martensite Austenitize + Quench Intercritical Anneal + Quench
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8 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Step 3. Diffuse Carbon from Supersaturated Martensite - Phase compositions change - Phase boundaries stationary
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9 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Q&P Process Schematic
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10 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 New Processing Concept (Sheet, Bar,…etc) Use carbon partitioning intentionally… from partially transformed martensite to untransformed austenite. Usually precluded because carbide precipitation occurs during tempering of martensite. Result: carbon-enriched austenite
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11 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Thermodynamics of Carbon Partitioning
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12 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Important Questions How much can we enrich the austenite? That is…what are the “equilibrium” martensite and austenite compositions? Or…when does partitioning stop?
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13 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 “True” Metastable Equilibrium Fe 3 C % Carbon Temperature Fe 3 C
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14 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 “True” Metastable Equilibrium
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15 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 “True” Metastable Equilibrium CANNOT Apply!! Fe 3 C % Carbon Temperature Fe 3 C X alloy XX XX - The equilibrium phase fractions are fixed by the lever rule - The actual phase fractions were fixed by cooling below Ms!
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16 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 A New Equilibrium Condition was Hypothesized “Constrained Carbon Equilibrium” (CCE) - Iron atoms are completely immobile (the phase boundaries are stationary). - Carbon atoms are completely mobile. - Carbon diffuses until its chemical potential (activity) is equal in ferrite and austenite. - Assume…competing reactions are precluded by Si/Al
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17 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Properties of “Constrained Carbon Equilibrium” - Not a unique condition at any temperature! - Depends on initial phase fractions/compositions
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18 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 - Austenite may be more enriched or less enriched than ortho- or para- equilibrium T0T0 A3A3 Properties of “Constrained Carbon Equilibrium”
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19 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Properties of “Constrained Carbon Equilibrium” Carbon Constrained Equilibrium: Mass balance:
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20 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Key Characteristics of CCE - Almost all of the carbon should partition to austenite - Enrichment levels are potentially very high (Fe-0.5C)
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21 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Example CCE Calculations - 1.0%C Initial Austenite
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22 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 We have all the pieces to predict microstructure… Example Steel Composition: C=0.15 Mn=1.0 Si=1.5 M s ( o C)=539-423(%C)-30.4(%Mn)-12.1(%Cr)-17.7(%Ni)-7.5(%Mo) M s =445 o C (Steel) Intercritical Annealing T=810 o C f ~ 22%C ~ 0.68 wt. %M s ~222 o C f ~ 78% T IA =810 o C
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23 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Quench T = 150 o C Fraction of Martensite (Koistinen and Marburger) Final Microstructure f ~ 10% f M ~ 12% f ~ 78% Phase Compositions After 450 o C Partitioning C ~ 1.5% C M ~.0019% T q =150 o C T p =450 o C
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24 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Q&P Process Design Methodology ASSUME: - Complete partitioning of carbon to austenite - No competing reactions (carbide formation)
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25 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Calculations for Experimental Al-Steel (at QT) IA =0.5
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26 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Martensite Formation During Final Quench
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27 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Calculated Final Austenite Fraction in High-Al Steel
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28 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Effect of Intercritical Annealing Step
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29 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Effect of Manganese Content
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30 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Effect of Carbon Content
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31 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Example of DICTRA Simulation Solid-Solid Phase Transformations in Inorganic Materials 2005 Edited by J. Howe TMS (The Minerals, Metals & Materials Society), 2005 CARBON ENRICHMENT OF AUSTENITE AND CARBIDE PRECIPITATION DURING THE QUENCHING AND PARTITIONING (Q&P) PROCESS F.C. Rizzo 1, D.V. Edmonds 2, K. He 2, J.G. Speer 3, D.K. Matlock 3 and A. Clarke 3 1 Department of Materials Science and Metallurgy; Pontifícia Universidade Católica-Rio de Janeiro; RJ 22453-900, Brazil 2 School of Process, Environmental and Materials Engineering; University of Leeds; Leeds LS2 9JT, United Kingdom 3 Advanced Steel Processing and Products Research Center; Colorado School of Mines; Golden, CO 80401, USA
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32 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Simulation Conditions Steel composition: 0.19C-1.59Mn-1.63Si wt% Heat treatment: Fully austenitized at 900 o C, quenched to 293 o C to produce 68% martensite and partitioned at 400 o C. The thickness of the ferrite and austenite plates used in the simulation were 0.30 and 0.14 microns, respectively (obtained by TEM).
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33 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Carbon Concentration Profiles for ferrite and austenite
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34 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Carbon concentration profiles in and during partitioning under CCE at 400C, for a 0.19C-1.59Mn-1.63Si steel
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35 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Average carbon concentration as a function of time for (0.30m) and (0.14m) plates during partitioning at 400 o C
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36 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Variation of (a) carbon flux and (b) carbon activity at the interface during partitioning. Time plotted in a log scale
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37 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Carbon concentration (wt%) at and interfaces as a function of time during partitioning at 400 o C
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38 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Carbon flux and concentration in the center of (a) ferrite and (b) austenite plates as a function of time
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39 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 CONCLUSIONS 1.For the scale of microstructure investigated, carbon depletion from the ferrite during partitioning at 400C occurs quite rapidly, around 10 -1 seconds, while the austenite takes much longer, around 10 seconds, to achieve a uniform concentration. 2.Due to its rapid depletion, the carbon concentration in the center of the ferrite plate starts to decrease after 10 -3 seconds. After this time the driving force for carbide precipitation is gradually reduced. 3.Carbon enrichment of the austenite will promote, initially, a substantial increase in the carbon concentration at the interface and a progressive stabilization of the plate, advancing from the interface to the center. Full stabilization is achieved when the composition of the central region reaches a carbon concentration corresponding to room temperature M s.
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40 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Some Q&P Experimental Results
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41 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 TEM micrographs of the Q&P microstructure produced in a 0.19%C-1.59%Mn-1.63%Si TRIP steel composition Quenching to 260°C and partitioning at 400°C for 100 s: (a) bright-field image and (b) dark-field image using a (200) austenite reflection. (a) (b)
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42 Workshop Aplicações da Termodinamica Computacional a Siderurgia 2012 Total elongation vs. ultimate tensile strength for TRIP, Dual phase (DP), martensitic (M), and Q&P sheet steel products
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