To explore effective strategies for optimising the grain size of experimental steel, a thermal simulation experiment was utilised within a temperature range spanning from 650 °C to 950 °C, at strain rates varying from 0.1 to 10/s, with a true strain of 0.918. Through thermal compression, the grain size could be reduced from 103.4 μm in the forged sample to a minimum of 11.6 μm (0.1 s−1–950 °C). The double-hyperbolic sine constitutive model was developed based on the flow stress curves, with the thermal activation energy for plastic deformation determined to be 514.66 kJmol−1. The critical conditions for recrystallisation were identified as . Combined with microstructural observations, it was determined that grain refinement primarily occurred through the dynamic recrystallisation mechanism and the deformation induced ferrite transformation mechanism. Additionally, within the deformation temperature range spanning from 850 °C to 950 °C, residual austenite emerged and its distribution was affected by the temperature.
FrommeyerGBruexU. Microstructures and mechanical properties of high-strength Fe-Mn-Al-C light-weight TRIPLEX steels. Steel Res Int2006; 77: 9–10. https://doi.org/10.1002/srin.200606440
2.
ZuazoIHallstedtBLindahlB, et al.Low-density steels: complex metallurgy for automotive applications. JOM2014; 66: 1747–1758.
3.
HirschJ. Aluminium in innovative light-weight car design. Mater Trans2011; 52: 818–824.
4.
ZhangSZhangSYZhouHZ, et al.Preparation and characterization of Sn-3.0Ag-0.5Cu nano-solder paste and assessment of the reliability of joints fabricated by microwave hybrid heating. Mater Charact2024; 207: 113512.
5.
ShaoLZhangXYChenYW, et al.Why do cracks occur in the weld joint of Ti-22Al-25Nb alloy during post-weld heat treatment?Front Mater2023; 10: 1135407.
6.
RawatPPrakashUPrasad SVV. Phase transformation and hot working studies on high-Al Fe-Al-Mn-C ferritic low-density steels. J Mater Eng Perform2021; 30: 6297–6308.
7.
HuZLZhengJHuaL, et al.Investigation of forging formability, microstructures and mechanical properties of pre-hardening Al-Zn-Mg-Cu alloy. J Manuf Process2024; 131: 2082–2100.
8.
MandalGKStanfordNHodgsonP, et al.Effect of hot working on dynamic recrystallisation study of as-cast austenitic stainless steel. Mater Sci Eng A2012; 556: 685–695.
9.
MandalSJayalakshmMBhaduriAK, et al.Effect of strain rate on the dynamic recrystallization behavior in a nitrogen-enhanced 316L(N). Metall Mater Trans A2014; 45: 2014–5645.
10.
MandalGKStanfordNKumarT, et al.Role of precipitates in recrystallization mechanisms of Nb-Mo microalloyed steel. J Mater Eng Perform2018; 27: 6748–6757.
11.
LiCMHuangLZhaoMJ, et al.Influence of hot deformation on dynamic recrystallization behavior of 300 M steel: rules and modeling. Mater Sci Eng A2020; 797: 139925.
12.
KaarSKrizanDSchwabeJ, et al.Influence of the Al and Mn content on the structure-property relationship in density reduced TRIP-assisted sheet steels. Mater Sci Eng A2018; 735: 475–486.
13.
WuZQDingHLiHY, et al.Microstructural evolution and strain hardening behavior during plastic deformation of Fe–12Mn–8Al–0.8C steel. Mater Sci Eng A2013; 584: 150–155.
14.
RaabeDSpringerHGutierrez-UrrutiaI, et al.Alloy design, combinatorial synthesis, and microstructure–property relations for low-density Fe-Mn-Al-C austenitic steels. Jom2014; 66: 1845–1856.
15.
RenaultCChuryumovAYPozdniakovAV, et al.Microstructure and hot deformation behavior of FeMnAlCMo steel. J Mater Res Technol2020; 9: 4440–4449.
16.
AbediHRHanzakiAZLiuZ, et al.Continuous dynamic recrystallization in low density steel. Mater Des2017; 114: 55–64.
17.
AbediHRHanzakiAZOuKL, et al.Substructure hardening in duplex low density steel. Mater Des2017; 116: 472–480.
18.
ZhaoYHLiuKXZhangHB, et al.Dislocation motion in plastic deformation of nano polycrystalline metal materials: a phase field crystal method study. Adv Compos Hybrid Ma2022; 5: 2546–2556.
19.
XuXYWangXMLiJZ, et al.Hot workability characteristics of low-density Fe-4Al-1Ni ferritic steel. Mater Sci Eng A2021; 799: 140257.
20.
DongHSunXJ. Deformation induced ferrite transformation in low carbon steels. Curr Opin Solid St M2005; 9: 269–276.
21.
ChuryumovAYKazakovaAAPozdniakovAV, et al.Investigation of hot deformation behavior and microstructure evolution of lightweight Fe-35Mn-10Al-1C steel. Metals-Basel2022; 12: 831.
22.
ChuryumovAYKazakovaAA. Prediction of true stress at hot deformation of high manganese steel by artificial neural network modeling. Materials2023; 16: 1083.
23.
TaoCCZhouGHuangHJ, et al.Research on energy dissipation and dynamic recrystallization microstructure evolution behavior of NiTi alloy during hot deformation. Mater Charact2024; 208: 113673.
24.
LongXSuTXLuCH, et al.An insight into dynamic properties of SAC305 lead-free solder under high strain rates and high temperatures. Int J Impact Eng2023; 175: 104542.
25.
LongXGuoYSuYT, et al.Unveiling the damage evolution of SAC305 during fatigue by entropy generation. Int J Mech Sci2023; 244: 108087.
26.
ZhouXGWangXXLiX, et al.Modeling of the dynamic recrystallization of Ti microalloyed high-strength steel. Steel Res Int2022; 93: 2100461.
27.
WenDXLinYCChenJ, et al.Work-hardening behaviors of typical solution-treated and aged Ni-based superalloys during hot deformation. J Alloys Compd2015; 618: 372–379.
28.
DongCYZhaoXM. Dynamic recrystallization behavior and microstructure evolution of high-strength low alloy steel during hot deformation. J Mater Res Technol2023; 25: 6087–6098.
29.
SadenHZChris HJDHodgsonPD. A mechanical approach to quantify dynamic recrystallization in polycrystalline metals. Scripta Mater2005; 52: 299–304.
30.
SongYHLiYGLiHY, et al.Hot deformation and recrystallization behavior of a new nickel-base superalloy for ultra-supercritical applications. J Mater Res Technol2022; 19: 4308–4324.
31.
ZhangJBWuCJPengYY, et al.Hot compression deformation behavior and processing maps of ATI 718Plus superalloy. J Alloy Compd2020; 835: 155195.
32.
MirzadehHCabreraJMPradoJM, et al.Hot deformation behavior of a medium carbon microalloyed steel. Mater Sci Eng A2011; 528: 3876–3882.
33.
PengYLiangSCLiuCY, et al.Dynamic recrystallization behavior under inhomogeneous thermomechanical deformation state. Steel Res Int2023; 94: 2200574.
34.
CaiJLiFLiuT, et al.Constitutive equations for elevated temperature flow stress of Ti-6Al-4 V alloy considering the effect of strain. Mater Des2011; 32: 1144.
35.
LinYCChenMSZhongJ. Constitutive modeling for elevated temperature flow behavior of 42CrMo steel. Comp Mater Sci2008; 42: 470.
36.
HeAChenLHuS, et al.Constitutive analysis to predict high temperature flow stress in 20CrMo continuous casting billet. Mater Des2013; 46: 54.
37.
WangWRenLGLiuHN, et al.Hot deformation behavior of a marine engineering steel for novel 980 MPa grade extra-thick plate. Steel Res Int2024; 95: 2300642.
38.
SonKTKimMHKimSW, et al.Evaluation of hot deformation characteristics in modiffed AA5052 using processing map and activation energy map under deformation heating. J Alloy Compd2018; 740: 96–108.
39.
LiuGMWangJBJiYF, et al.Hot deformation behavior and microstructure evolution of Fe–5Mn–3Al–0.1C high-strength lightweight steel for automobiles. Materials2021; 14: 2478.
40.
MohamadizadehAZarei-HanzakiAAbediHR. Modiffed constitutive analysis and activation energy evolution of a low-density steel considering the effects of deformation parameters. Mech Mater2016; 95: 60–70.
41.
WuZTangYChenW, et al.Exploring the influence of Al content on the hot deformation behavior of Fe-Mn-Al-C steels through 3D processing map. Vacuum2019; 159: 447–455.
42.
ShengSLQiaoYXZhaiRZ, et al.Processing map and dynamic recrystallization behaviours of 316LN-Mn austenitic stainless steel. Int J Miner Metall Mater2023; 30: 2386–2396.
43.
LiuDGTongZKHanD, et al.Study on the inffuence of κ-carbide on the high temperature flow behavior of the medium-Mn lightweight steel: modeling and characterization. Mater Sci Eng A2024; 908: 146784.
44.
ZhaoYH. Stability of phase boundary between L12-Ni3Al phases: a phase feld study. Intermetallics2022; 144: 107528.
45.
SunXYZhangMWangY, et al.Kinetics and numerical simulation of dynamic recrystallization behavior of medium Mn steel in hot working. Steel Res Int2020; 91: 1900675.
46.
HadadzadehaAMokdadFWellsMA, et al.A new grain orientation spread approach to analyze the dynamic recrystallization behavior of a cast-homogenized Mg-Zn-Zr alloy using electron backscattered diffraction. Mater Sci Eng A2018; 709: 285–289.
47.
LiCMLiuYTanYB, et al.Hot deformation behavior and constitutive modeling of H13-MOD steel. Metals2018; 8: 846.
48.
MittemeijerEJ. Recovery, recrystallization and grain growth. Berlin: Springer, 2010.
49.
ZhengGMMaoXNLiL, et al.The variation of microstructures, textures and mechanical properties from edge to center in cross section of Ti6242 s titanium alloy. Vacuum2019; 160: 81.
50.
WangMJSunCYFuMW, et al.Study on the dynamic recrystallization mechanisms of INCONEL 740 superalloy during hot deformation. J Alloy Compd2020; 820: 153325.
51.
HuangKLogéRE. A review of dynamic recrystallization phenomena in metallic materials. Mater Des2016; 111: 548.
QianDSChenJCLuoH, et al.Electric current-induced directional slip of dislocation and grain boundary ordering. Mater Today Adv2024; 24: 100530.
54.
WangBZhaoHLShanXZ, et al.Hot deformation behavior and dynamic recrystallization mechanism of Ti2ZrTa0.75 refractory complex concentrated alloy. Mater Charact2023; 203: 113061.
55.
HaoLHSunMYXiaoNM, et al.Characterizations of dynamic strain-induced transformation in low carbon steel. J Mater Sci Technol2012; 28: 1095.
56.
WangHLQianDSWangF. Predictive mechanical property and fracture behavior in high-carbon steel containing high-density carbides via artiffcial RVE modeling. Mater Des2024; 247: 113383.
57.
WangZTNingYQDiP, et al.Understanding the fracture mechanisms of Ni–Co–Cr-type superalloys: role of precipitate evolution and strength degradation. Mater Sci Eng A2024; 902: 146623.
58.
HuangMHWangLYWangCC, et al.Optimizing crack initiation energy in austenitic steel via controlled martensitic transformation. J Mater Sci Technol2024; 198: 231–242.
