CLC number: TG31
On-line Access: 2024-08-27
Received: 2023-10-17
Revision Accepted: 2024-05-08
Crosschecked: 2020-10-28
Cited: 0
Clicked: 3594
Yong-gen Sun, Yu-shi Qi, Jiao Li, Zhi-ming Du, Li-li Chen, Li-hua Chen. Fabrication and performance analyses of 45# steel supports using liquid forging[J]. Journal of Zhejiang University Science A, 2020, 21(11): 908-922.
@article{title="Fabrication and performance analyses of 45# steel supports using liquid forging",
author="Yong-gen Sun, Yu-shi Qi, Jiao Li, Zhi-ming Du, Li-li Chen, Li-hua Chen",
journal="Journal of Zhejiang University Science A",
volume="21",
number="11",
pages="908-922",
year="2020",
publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.A2000012"
}
%0 Journal Article
%T Fabrication and performance analyses of 45# steel supports using liquid forging
%A Yong-gen Sun
%A Yu-shi Qi
%A Jiao Li
%A Zhi-ming Du
%A Li-li Chen
%A Li-hua Chen
%J Journal of Zhejiang University SCIENCE A
%V 21
%N 11
%P 908-922
%@ 1673-565X
%D 2020
%I Zhejiang University Press & Springer
%DOI 10.1631/jzus.A2000012
TY - JOUR
T1 - Fabrication and performance analyses of 45# steel supports using liquid forging
A1 - Yong-gen Sun
A1 - Yu-shi Qi
A1 - Jiao Li
A1 - Zhi-ming Du
A1 - Li-li Chen
A1 - Li-hua Chen
J0 - Journal of Zhejiang University Science A
VL - 21
IS - 11
SP - 908
EP - 922
%@ 1673-565X
Y1 - 2020
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/jzus.A2000012
Abstract: In this paper, 45# steel supports prepared by liquid forging showed excellent performances and the effects of processing techniques on the development of microstructures and mechanical properties of these steel supports were researched. The liquid forging process was simulated and technological parameters were optimized via a ProCAST simulation software. The solidification time, temperature distribution, first principal stress distribution of the 45# steel supports varied with time, temperatures, and position. Two principal parameters, pouring temperature and dwell time, were assessed for their effects on microstructures, mechanical properties, and wear resistance properties of 45# steel supports. Results showed that the optimal pouring temperature of the molten metal and the pressure-holding time were between 1540 °C and 1560 °C and between 35 s and 40 s, respectively. The microstructure, mechanical properties, and fracture behavior of different positions in the support were also discussed, and the central position performed better than the edge because of plastic deformation. Finally, the dynamic solidification process was also investigated and the liquid forging process of 45# steel supports was complex and contained some special metal liquid convection and several plastic deformation stages.
[1]Bi GJ, Ng GKL, Teh KM, et al., 2010. Feasibility study on the laser aided additive manufacturing of die inserts for liquid forging. Materials & Design, 31(S1):S112-S116.
[2]Bratu V, Mortici C, Oros C, et al., 2014. Mathematical model of solidification process in steel continuous casting taking into account the convective heat transfer at liquid-solid interface. Computational Materials Science, 94:2-7.
[3]Cheng YS, Zhang YY, Du ZM, 2010. Liquid forging integral forming technology for aluminum matrix composites with local reinforcement. Special Casting & Nonferrous Alloys, 30(3):231-233 (in Chinese).
[4]Dong J, Li C, Liu CX, et al., 2017. Hot deformation behavior and microstructural evolution of Nb-V-Ti microalloyed ultra-high strength steel. Journal of Materials Research, 32(19):3777-3787.
[5]Du ZM, Chen G, Han F, et al., 2011. Homogenization on microstructure and mechanical properties of 2A50 aluminum alloy prepared by liquid forging. Transactions of Nonferrous Metals Society of China, 21(11):2384-2390.
[6]Escobar DP, de Dafé SSF, Verbeken K, et al., 2016. Effect of the cold rolling reduction on the microstructural characteristics and mechanical behavior of a 0.06%C-17%Mn TRIP/TWIP steel. Steel Research International, 87(1):95-106.
[7]Fang XG, Lü SL, Zhao L, et al., 2016. Microstructure and mechanical properties of a novel Mg-RE-Zn-Y alloy fabricated by Rheo-Squeeze casting. Materials & Design, 94:353-359.
[8]Gao B, Chen XF, Pan ZY, et al., 2019. A high-strength heterogeneous structural dual-phase steel. Journal of Materials Science, 54(19):12898-12910.
[9]Guo J, Liu LG, Li Q, et al., 2013. Characterization on carbide of a novel steel for cold work roll during solidification process. Materials Characterization, 79:100-109.
[10]Hirt G, Khizhnyakova L, Baadjou R, et al., 2009. Semi-solid forming of aluminium and steel-introduction and overview. In: Hirt G, Kopp R (Eds.), Thixoforming: Semi-solid Metal Processing. Wiley-VCH Verlag GmbH & Co. KGaA, New York, USA, p.1-27.
[11]Li HJ, Luo SJ, Qi LH, 1992. The stress states of a workpiece in the process of liquid-metal forging. Journal of Materials Processing Technology, 30(3):287-296.
[12]Li JY, Cheng GG, Li LY, et al., 2018. The formation mechanism of Mn-Al-O inclusions in Fe-Cr-Mn stainless steel during continuous casting. Steel Research International, 89(5):1700461.
[13]Li N, Xing SM, Bao PW, 2013. Microstructure and mechanical properties of nodular cast iron produced by melted metal die forging process. Journal of Iron and Steel Research, 20(6):58-62.
[14]Li SL, Sun WL, Wang HQ, et al., 2011. Study on microstructures and mechanical properties of AlSi9Cu3 aluminum alloy fabricated by liquid forging. Advanced Materials Research, 418-420:353-356.
[15]Linz M, Rodríguez Ripoll M, Gachot C, et al., 2017. On the competition between plastic deformation and material detachment in Ferritic/Pearlitic steel under boundary lubrication. Wear, 376-377:813-821.
[16]Liu FB, Wang JD, Chen DR, et al., 2010. The cavitation erosion of the 45# carbon steels implanted with titanium and nitrogen. Tribology Transactions, 53(2):239-243.
[17]Ma XP, Li DZ, 2016. Multiscale discrete crystal growth in the solidification of 20SiMnMo5 steel. Crystal Growth & Design, 16(6):3163-3169.
[18]Mitchell A, 1997. Melting, casting, and forging problems in titanium alloys. JOM, 49(6):40-42.
[19]Morin D, Hopperstad OS, Benallal A, 2018. On the description of ductile fracture in metals by the strain localization theory. International Journal of Fracture, 209(1):27-51.
[20]Murali S, Yong MS, 2010. Liquid forging of thin Al-Si structures. Journal of Materials Processing Technology, 210(10):1276-1281.
[21]Niu CN, LaRosa CR, Miao JS, et al., 2018. Magnetically-driven phase transformation strengthening in high entropy alloys. Nature Communications, 9(1):1363.
[22]Niu R, Li BK, Liu ZQ, et al., 2018. Melting of moving strip during steel strip feeding in continuous casting process. Steel Research International, 89(5):1700407.
[23]Püttgen W, Hallstedt B, Bleck W, et al., 2007. On the microstructure and properties of 100Cr6 steel processed in the semi-solid state. Acta Materialia, 55(19):6553-6560.
[24]Qin F, Feng W, Wu ST, 2018. Microstructure and Vickers-hardness of 20CrMnTiH steel during hot compression testing. Ironmaking & Steelmaking, 45(6):537-543.
[25]Rogal Ł, Dutkiewicz J, 2012. Effect of annealing on microstructure, phase composition and mechanical properties of thixo-cast 100Cr6 steel. Materials Characterization, 68:123-130.
[26]Song GW, Tama BA, Park J, et al., 2019. Temperature control optimization in a steel-making continuous casting process using a multimodal deep learning approach. Steel Research International, 90(12):1900321.
[27]Sosenushkin EN, Frantsuzova LS, Kozlova EM, 2015. Effect of pressure and temperature factors on the solidification of cast iron and its structure in liquid forging. Metal Science and Heat Treatment, 57(5-6):309-316.
[28]Tsuchiyama T, Yamamoto S, Hata S, et al., 2016. Plastic deformation and dissolution of ε-Cu particles by cold rolling in an over-aged particle dispersion strengthening Fe-2mass%Cu alloy. Acta Materialia, 113:48-55.
[29]Viola E, Marzani A, Fantuzzi N, 2015. Interaction effect of cracks on flutter and divergence instabilities of cracked beams under subtangential forces. Engineering Fracture Mechanics, 151:109-129.
[30]Zheng CK, Zhang WW, Zhang DT, et al., 2015. Low cycle fatigue behavior of T4-treated Al-Zn-Mg-Cu alloys prepared by squeeze casting and gravity die casting. Transactions of Nonferrous Metals Society of China, 25(11):3505-3514.
Open peer comments: Debate/Discuss/Question/Opinion
<1>