Restricted accessResearch articleFirst published online 2013-3
Investigation on hot deformation of 20Cr–25Ni superaustenitic stainless steel with starting columnar dendritic microstructure based on kinetic analysis and processing map
The deformation behaviour of a 20Cr–25Ni superaustenitic stainless steel (SASS) with initial microstructure of columnar dendrites was investigated using the hot compression method at temperatures of 1000–1200°C and strain rates of 0·01–10 s−1. It was found that the flow stress was strongly dependent on the applied temperature and strain rate. The constitutive equation relating to the flow stress, temperature and stain rate was proposed for hot deformation of this material, and the apparent activation energy of deformation was calculated to be 516·7 kJ mol−1. Based on the dynamic materials model and the Murty's instability criterion, the variations of dissipation efficiency and instability factor with processing parameters were studied. The processing map, combined with the instability map and the dissipation map, was constructed to demonstrate the relationship between hot workability and microstructural evolution. The stability region for hot processing was inferred accurately from the map. The optimum hot working domains were identified in the respective ranges of the temperature and the strain rate of 1025–1120°C and 0·01–0·03 s−1 or 1140–1200°C and 0·08–1 s−1, where the material produced many more equiaxed recrystallised grains. Moreover, instability regimes that should be avoided in the actual working were also identified by the processing map. The corresponding instability was associated with localised flow, adiabatic shear band, microcracking and free surface cracks.
FondaRW, LauridsenEM, LudwigW, TafforeauP, SpanosG: ‘Two-dimensional and three-dimensional analyses of sigma precipitates and porosity in a superaustenitic stainless steel’,Metall. Mater. Trans. A, 2007, 38A, 2721–2726.
2.
LeeTH, KimSJ, JungYC: ‘Crystallographic details of precipitates in Fe–22Cr–21Ni–6Mo–(N) superaustenitic stainless steels aged at 900°C’,Metall. Mater. Trans. A, 2000, 31A, 1713–1723.
HeinoS: ‘Role of Mo and W during sensitization of superaustenitic stainless steel–crystallography and composition of precipitates’,Metall. Mater. Trans. A, 2000, 31A, 1893–1905.
MatayaMC, NilssonER, BrownEL, KraussG: ‘Hot working and recrystallization of as-cast 316L’,Metall. Mater. Trans. A, 2003, 34A, 1683–1703.
8.
AsliAH, Zarei-HanzakiA: ‘Dynamic recrystallization behavior of a Fe–Cr–Ni super-austenitic stainless steel’,J. Mater. Sci. Technol., 2009, 25, 603–606.
9.
MomeniA, DehghaniK, KeshmiriH, EbrahimiGR: ‘Hot deformation behavior and microstructural evolution of a superaustenitic stainless steel’,Mater. Sci. Eng. A, 2010, A527, 1605–1611.
10.
EbrahimiGR, KeshmiriH, MomeniA, MazinaniM: ‘Dynamic recrystallization behavior of a superaustenitic stainless steel containing 16%Cr and 25%Ni’,Mater. Sci. Eng. A, 2011, A528, 7488–7493.
11.
MatayaMC, NilssonER, BrownEL, KraussG: ‘Hot working and recrystallization of as-cast 317L’,Metall. Mater. Trans. A, 2003, 34A, 3021–3041.
12.
PrasadYVRK, SasidharaS: ‘Hot working guide: a compendium of processing maps’; 1997, Materials Park, OH, ASM.
13.
MurtySVSN, RaoBN, KashyapBP: ‘Identification of flow instabilities in the processing maps of AISI 304 stainless steel’,J. Mater. Process. Technol., 2005, 166, 268–278.
14.
TanSP, WangZH, ChengSC, LiuZD, HanJC, FuWT: ‘Processing maps and hot workability of Super304H austenitic heat-resistant stainless steel’,Mater. Sci. Eng. A, 2009, A517, 312–315.
15.
MomeniA, DehghaniK: ‘Characterization of hot deformation behavior of 410 martensitic stainless steel using constitutive equations and processing maps’,Mater. Sci. Eng. A, 2010, A527, 5467–5473.
16.
ChenL, MaXC, LiuXA, WangLM: ‘Processing map for hot working characteristics of a wrought 2205 duplex stainless steel’,Mater. Des., 2011, 32, 1292–1297.
17.
HanY, ZouDN, ChenZY, FanGW, ZhangW: ‘Investigation on hot deformation behavior of 00Cr23Ni4N duplex stainless steel under medium–high strain rates’,Mater. Charact., 2011, 62, 198–203.
18.
WangZH, FuWT, WangBZ, ZhangWH, LvZQ, JiangP: ‘Study on hot deformation characteristics of 12%Cr ultra-super-critical rotor steel using processing maps and Zener–Hollomon parameter’,Mater. Charact., 2010, 61, 25–30.
19.
SamantarayD, MandalS, KumarV, AlbertSK, BhaduriAK, JayakumarT: ‘Optimization of processing parameters based on high temperature flow behavior and microstructural evolution of a nitrogen enhanced 316L(N) stainless steel’,Mater. Sci. Eng. A, 2012, A552, 236–244.
20.
MomeniA, DehghaniK: ‘Hot working behavior of 2205 austenite-ferrite duplex stainless steel characterized by constitutive equations and processing maps’,Mater. Sci. Eng. A, 2011, A528, 1448–1454.
21.
MurtySVSN, RaoBN: ‘On the development of instability criteria during hotworking with reference to IN 718’,Mater. Sci. Eng. A, 1998, A254, 76–82.
22.
MurtySVSN, RaoBN: ‘On the flow localization concepts in the processing maps of titanium alloy Ti–24Al–20Nb’,J. Mater. Process. Technol., 2000, 104, 103–109.
23.
VenugopalS, MannanSL, PrasadYVRK: ‘Optimization of cold and warm workability in stainless steel type AISI 316L using instability maps’,J. Nucl. Mater., 1995, 227, 1–10.
24.
SamantarayD, MandalS, BhaduriAK: ‘Characterization of deformation instability in modified 9Cr–1Mo steel during thermo-mechanical processing’,Mater. Des., 2011, 32, 716–722.
25.
MurtySVSN, RaoBN: ‘Instability map for hot working of 6061Al–10 vol% Al2O3 metal matrix composite’,J. Phys. D, 1998, 31D, 3306–3311.
26.
YuJW, LiuXF, XieJX: ‘Study of dynamic recrystallization of a Cu-based alloy BFe10–1–1 with continuous columnar grains’,Acta Metall. Sinica, 2011, 47, 482–488.
27.
SellarsC, MctegartW: ‘On the mechanism of hot deformation’,Acta Metall., 1966, 14, 1136–1138.
28.
LinYC, XiaYC, ChenXM, ChenMS: ‘Constitutive descriptions for hot compressed 2124-T851 aluminum alloy over a wide range of temperature and strain rate’,Comput. Mater. Sci., 2010, 50, 227–233.
29.
El WahabiM, CabreraJM, PradoJM: ‘Hot working of two AISI 304 steels: a comparative study’,Mater. Sci. Eng. A, 2003, A343, 116–125.
30.
FarnoushH, MomeniA, DehghaniK, MohandesiJA, KeshmiriH: ‘Hot deformation characteristics of 2205 duplex stainless steel based on the behavior of constituent phases’,Mater. Des., 2010, 31, 220–226.
31.
MomeniA, DehghaniK: ‘Microstructural evolution and flow analysis during hot working of a Fe–Ni–Cr superaustenitic stainless steel’,Metall. Mater. Trans. A, 2011, 42A, 1925–1932.
32.
LinYC, LiuG: ‘Effects of strain on the workability of a high strength low alloy steel in hot compression’,Mater. Sci. Eng. A, 2009, A523, 139–144.
33.
PrasadYVRK, SeshacharyuluT: ‘Modelling of hot deformation for microstructural control’,Int. Mater. Rev., 1998, 43, 243–258.
34.
SunY, ZengWD, ZhaoYQ, ZhangXM, ShuY, ZhouYG: ‘Research on the hot deformation behavior of Ti40 alloy using processing map’,Mater. Sci. Eng. A, 2011, A528, 1205–1211.
35.
SamantarayD, MandalS, BhaduriAK: ‘Optimization of hot working parameters for thermo-mechanical processing of modified 9Cr–1Mo(P91) steel employing dynamic materials model’,Mater. Sci. Eng. A, A528, 5204–5211.
36.
RajR: ‘Development of a processing map for use in warm-forming and hot-forming processes’,Metall. Trans. A, 1981, 12A, 1089–1097.
37.
RamanathanS, KarthikeyanR, GanesanG: ‘Development of processing maps for 2124 Al/SiCp composites’,Mater. Sci. Eng. A, 2006, A441, 321–325.
38.
SivakesavamO, PrasadYVRK: ‘Characteristics of superplasticity domain in the processing map for hot working of as-cast Mg–11·5Li–1·5Al alloy’,Mater. Sci. Eng. A, 2002, A323, 270–277.
