Effect of Heat Treatment on Microstructure Evolution and Fracture Mechanism of 30CrMo/316L Multilayered Composites Fabricated by Vacuum Electron Beam Welding and Accumulative Hot Roll Bonding

doi:10.1007/s40195-025-01933-y

Abstract

Abstract:

The effects of accumulative hot rolling followed by solution treatment on the microstructural evolution and fracture behavior of 30CrMo/316L multilayered composites have been investigated. A scanning electron microscope equipped with an electron backscatter diffraction probe, a laser confocal microscope, an electron probe microanalysis, and a universal testing machine were employed to characterize the microstructures and mechanical properties. The results indicate that solution treatment transformed the microstructure of the 30CrMo layer from ferrite to martensite, while the 316L layer remained austenitic but transitioned from the rolled to the recrystallized state. Additionally, solution treatment significantly enhanced the mechanical properties of the composite, leading to an increase in yield strength and ultimate tensile strength to 744 and 1106 MPa, respectively—258 and 276 MPa higher than those of the hot-rolled plate. The enhancement in strength is primarily attributed to the formation of high-strength martensite in the 30CrMo layer. During deformation, the composite interface effectively impeded crack propagation and induced step-like deflection. However, the formation of cross-layer grains facilitated crack nucleation at grain boundaries, leading to rapid crack propagation and instantaneous fracture. Therefore, preventing the formation of cross-layer grains during the heat treatment process is crucial, as their presence weakens the interfacial strengthening effect of the composite plate. This study provides valuable insights for the design and development of multi-layered steels.

Key words: 30CrMo/316L multilayered composite, Accumulative rolling, Solution treatment, Microstructural evolution, Fracture mechanism

Ming-Rong Fan, Tian-Yu Wang, Jing-Gang Suo, Ming-Kun Wang, Ying-Ying Feng, Zong-An Luo. Effect of Heat Treatment on Microstructure Evolution and Fracture Mechanism of 30CrMo/316L Multilayered Composites Fabricated by Vacuum Electron Beam Welding and Accumulative Hot Roll Bonding[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(12): 2265-2278.

Figures/Tables 16

Table 1 Chemical component of raw materials (mass fraction, %)

Materials	C	Si	Mn	Cr	Ni	Mo	P	S	Fe
30CrMo	0.30	0.22	0.62	0.88	0.03	0.12	0.03	0.03	Bal.
316L	0.02	0.50	1.20	16.7	10.6	2.12	0.02	0.02	Bal.

Fig. 1 Schematic diagram of vacuum accumulative hot roll bonding process and specimens for mechanical properties testing (mm) of 30CrMo/316L MLS

Fig. 2 SEM morphologies a, b, secondary electron morphology c and EPMA element distribution characteristics d-h of hot-rolled 30CrMo/316L composite plates

Fig. 3 OM and SEM morphologies of 30CrMo/316L composite plates at different solution temperatures: a, b S950; c, d S1050; e, f S1150

Fig. 4 Element distribution around the uncorroded grain boundary of 30CrMo layer (S1050): a Cr, Ni, Mo, Mn elements; b C element

Fig. 5 Element distribution in the precipitate region of the 316L layer after solution treatment (S1050): a secondary electron morphology; b C element; c Cr element; d Ni element; e Mo element; f Mn element

Table 2 Precipitate composition in 316L layer (mass fraction, %)

Location	C	Cr	Ni	Mo	Mn	Fe
1	2.39	16.79	5.54	0.83	2.25	72.03
2	3.21	14.63	3.11	0.02	1.83	77.20
3	14.03	35.02	3.94	5.34	1.34	40.01
4	7.37	28.86	6.15	4.89	2.08	50.65

Fig. 6 Element distribution at the composite interface after solution treatment at different temperatures: a, b S950; c, d S1050; e, f S1150

Fig. 7 Tensile and bending test curves under different conditions: a tensile test results; b bending test results; c macroscopic images before and after the tensile

Table 3 Tensile properties of 30CrMo/316L composite plates under different conditions

Solution temperature (°C)	Yield strength (MPa)	Tensile strength (MPa)	Yield ratio	Elongation (%)
950	682	980	0.696	25.2
1050	727	1048	0.694	21.4
1150	744	1106	0.673	18.1
Without solution	486	830	0.586	31.7

Fig. 8 Tensile fracture morphologies of composite plates at different solution temperatures

Fig. 9 Microstructure evolution of the 30CrMo/316L composite during heating in the solution treatment process

Fig. 10 Microstructure evolution during holding and cooling

Fig. 11 EBSD and test results near the cross-layer grain interface and XRD diffraction pattern at different temperatures: a BC diagram; b IPF diagram; c phase diagram; d XRD diffraction pattern

Fig.12 Fracture failure process of the hot-rolled 30CrMo/316L composite plate: a necking; b slip bands; c shrinkage formation; d shrinkage expansion; e crack extension; f fracture

Fig. 13 Fracture failure process of 30CrMo/316L composite plate after solution treatment at 1150 °C: a necking; b, c slip bands; d shrinkage formation; e fracture; f transverse crack

References 35

[1]	Z. Wei, P. Huang, X. Su, Q. Gao, Z. Feng, L. Peng, J. Li, G. Zu, Mater. Sci. Eng. A 919, 147485 (2025)
[2]	Y. Liu, Z. Zheng, J. Long, Z. Xu, S. Jiao, Y. Qiao, K. Zheng, F. Yin, J. Mater. Res. Technol. 26, 556 (2023) DOI URL
[3]	X. Tang, Q. Peng, J. Long, X. Wang, Y. Lin, L. Deng, J. Jin, P. Gong, M. Zhang, M.G. Lee, J. Mater. Sci. Technol. 229, 67 (2025) DOI URL
[4]	Z.A. Luo, L.Y. Mao, C. Huang, H.Y. Zhou, M.K. Wang, Mater. Des. 237, 112549 (2024) DOI URL
[5]	L.R. Resendiz, M.E. Tahawy, T. Zhang, M.C. Rossi, D.M. Cardona, T. Yang, V. Amigó-Borrás, Y. Huang, H. Mirzadeh, I.J. Beyerlein, J.C. Huang, T.G. Langdon, Y.T. Zhu, Mater. Sci. Eng. R 150, 100691 (2022)
[6]	D. Wang, Q. Wang, X. Li, Z. Zhang, Acta Metall. Sin.-Engl. Lett. 37, 840 (2024)
[7]	R. Wang, Y. Weng, J. Lu, J. Guo, X. Sui, Z. Song, H. Wang, D. Wei, X. Ren, X. Li, D. Wang, Q. Wang, X. Li, Z. Zhang, Vacuum 217, 112483 (2023)
[8]	Y. Zheng, X. Hu, H. Jiang, L. Rong, Acta Metall. Sin.-Engl. Lett. 37, 2163 ( 2024)
[9]	J. Yang, X. Li, H. Yao, Y. Guan, Acta Metall. Sin.-Engl. Lett. 35, 1357 (2022)
[10]	J. Ding, B. Liu, B. Zhang, J.F. Zhao, B. Li, J. Feng, P. Ji, X. Luo, F. Yin, Metall. Mater. Trans. A 55, 3107 (2024)
[11]	J. Li, B. Feng, X. Feng, X. Chen, K. Zheng, X. Jiang, F. Pan, J. Magnes. Alloy. 13, 3237 (2025) DOI URL
[12]	B. Yang, Z. Li, K. Fan, B. Liu, W. Yu, F. Yin, Crystals 12, 1652 (2022)
[13]	W.X. Yu, B.X. Liu, X.P. Cui, Y.C. Dong, X. Zhang, J.N. He, C.X. Chen, F.X. Yin, Mater. Sci. Eng. A 727, 70 (2018)
[14]	X. Ma, C. Huang, J. Moering, M. Ruppert, H. Höppel, M. Göken, J. Narayan, Y. Zhu, Acta Mater. 116, 43 (2016) DOI URL
[15]	C.X. Huang, Y.F. Wang, X.L. Ma, S. Yin, H.W. Höppel, M. Göken, X.L. Wu, H.J. Gao, Y.T. Zhu, Mater. Today 21, 713 (2018)
[16]	D. Yang, Z. Luo, G. Xie, M. Wang, R.D.K. Misra, J. Iron. Steel Res. Int. 25, 72 (2018) DOI
[17]	G.N.M. Rao, V.R.M. Kumar, Mater. Today 56, 13 (2022)
[18]	K.R. Ramkumar, I. Dinaharan, N. Murugan, H.S. Kim, J. Mater. Sci. 59, 8606 (2024) DOI
[19]	Q. Ye, X. Li, M. Tayyebi, A.H. Assari, A. Polkowska, S. Lech, W. Polkowski, M. Tayebi, Arch. Civ. Mech. Eng. 23, 27 (2022) DOI
[20]	D. Rahmatabadi, M. Tayyebi, R. Hashemi, G. Faraji, Powder Metall. Met. Ceram. 57, 144 (2018) DOI
[21]	D. Rahmatabadi, M. Pahlavani, M.D. Gholami, J. Marzbanrad, R. Hashemi, J. Mater. Res. Technol. 9, 7880 (2020) DOI
[22]	Z. Dai, H. Chen, J. Sun, S. van der Zwaag, J. Sun, Acta Mater. 268, 119791 (2024) DOI URL
[23]	J. Chai, H. Dong, J.Y. Zhang, K. Shen, Z. Yang, H. Chen, Scr. Mater. 247, 116109 (2024) DOI URL
[24]	G. Shin, M. Ebrahimian, N.K. Adomako, H. Choi, D.J. Lee, J.H. Yoon, D.W. Kim, J.Y. Kang, M.Y. Na, H.J. Chang, J.H. Kim, Mater. Des. 227, 111681 (2023) DOI URL
[25]	P. Huang, Q. Xiao, W. Hu, B. Huang, D. Yuan, Metals 14, 454 (2024)
[26]	L. Xu, Y. He, Y. Kang, J. Jung, K. Shin, Materials 15, 4704 (2022)
[27]	Z. Zhou, J. Lv, M. Gui, W. Yang, Int. J. Plast. 178, 104008 (2024) DOI URL
[28]	Y. Wei, Q. Lu, Z. Kou, T. Feng, Q. Lai, Mater. Sci. Eng. A 862, 144424 (2023)
[29]	X. Zhou, R. Cao, J. Ma, X. Jiang, Y. Yan, Eng. Fract. Mech. 314, 110726 (2025) DOI URL
[30]	W.X. Yu, B.X. Liu, J.F. Zhao, Z.M. Lin, S.J. Zheng, F.X. Yin, N. Hu, Scr. Mater. 241, 115865 (2024) DOI URL
[31]	R. Cao, X. Yu, Z. Feng, M. Ojima, J. Inoue, T. Koseki, Metall. Mater. Trans. A 47, 6042 (2016)
[32]	R. Cao, Y. Ding, Y. Yan, X. Zhang, J. Chen, Compos. Interfaces 26, 1069 (2019)
[33]	C. Jeong, T. Oya, J. Yanagimoto, J. Mater. Process. Technol. 213, 614 (2013) DOI URL
[34]	R.I. Barabash, O.M. Barabash, M. Ojima, Z. Yu, J. Inoue, S. Nambu, T. Koseki, R. Xu, Z. Feng, Metall. Mater. Trans. A 45, 98 (2014)
[35]	Z. Li, Q. Yuan, S. Xu, Y. Zhou, S. Liu, G. Xu, Materials 16, 3840 (2023)