Effect of Intercritical Annealing Prior to Quenching and Partitioning on Impact Abrasive Wear Properties of Medium-Manganese Steel

doi:10.1007/s40195-025-01847-9

Abstract

Abstract:

Medium-manganese steel exhibits excellent strength and toughness, which are essential features in wear resistance applications. This study examines the impact of annealing temperature on impact abrasive wear. The results have indicated that samples annealed at different temperatures display plowing and fatigue wear effects. In the initial wear stage, the high-temperature annealed steel outperforms samples annealed at a lower temperature in terms of anti-plowing wear performance. This phenomenon is mainly due to the lower initial hardness of the samples subjected to low-temperature annealing. However, with prolonged wear time, the low-temperature annealed samples exhibit improved plowing wear performance, which is ascribed to a refinement of the lamellar microstructure and an increased residual austenite (RA), which enhances the work hardening effect, improving the hardness of the worn surface. The low-temperature annealed samples consistently delivered superior fatigue wear performance when compared with samples annealed at the higher temperature. The latter effect may be attributed to two factors. Firstly, the finer lamellar microstructure in the low-temperature annealed samples, coupled with greater RA, results in transformation-induced plasticity or twin-induced plasticity effect that hinders crack formation and propagation. Secondly, the low-temperature annealed samples form nanoscale equiaxed grains near the worn surface during the wear process. These grains can withstand crack driving forces in fine-grained regions, suppressing the formation and propagation of cracks.

Key words: Impact abrasive wear, Residual austenite, Fatigue, Plowing

Shaolong Zhang, Wen Zhou, Feng Hu, Kaiming Wu, Serhii Yershov. Effect of Intercritical Annealing Prior to Quenching and Partitioning on Impact Abrasive Wear Properties of Medium-Manganese Steel[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(6): 1041-1056.

Figures/Tables 16

Table 1 Mass fraction of each element in MMS (wt%)

C	Si	Mn	Al	Mo + Ni + Cr + Nb	Fe
0.30	0.26	4.85	1.16	1.03	Bal.

Fig. 1 Heat treatment process diagram

Table 2 Mechanical properties of experimental steel

Sample	R_m (MPa)	R_p0.2 (MPa)	TEL (%)	α_k (J/cm²)	$\alpha_{\text{k}}^{\text{v}}$ (J/cm²)	Hardness (HV_0.2)
IA700	1016 ± 3	765 ± 6	33.5 ± 0.2	576 ± 7	53 ± 3	286 ± 6
IA750	1572 ± 1	806 ± 8	16.7 ± 0.4	424 ± 6	42 ± 1	301 ± 11

Fig. 2 Chart of impact abrasive wear testing machine. MCA: microstructure characterization area

Fig. 3 SEM images showing sample microstructure: a IA700, b IA750

Fig. 4 TEM images and selected-area electron diffraction (SAED) patterns: a-c IA700, d-f IA750

Fig. 5 EBSD results of IA700 a-c and IA750 d-f samples: a and d IPF diagrams; b and e IPF diagrams of residual austenite; c and f effective grain size statistics map

Fig. 6 a Amount of wear and b cumulative wear in each cycle as a function of wear time; distribution of Vickers hardness after c 30 min, d 120 min testing

Fig. 7 Wear surface morphologies of both samples: a-d IA700, e-h IA750

Fig. 8 SEM images of the longitudinal section of samples after 120 min of abrasive wear: a and c IA700; b and d IA750

Fig. 9 EBSD analysis results at different positions from the wear surface of the samples: a-c and d-f IPF diagrams of IA700 and IA750 samples, respectively; a1-c1 and d1-f1 effective grain size statistics map of IA700 and IA750 samples, respectively

Fig. 10 XRD patterns of the samples before and after wear

Fig. 11 TEM images and selected-area electron diffraction near the worn surface at different wear stages: a-d IA700, e-h IA750

Fig. 12 High-resolution transmission electron microscopy (HRTEM) and GPA images of ferrite at different positions in IA700 samples: a and b located between martensite; c and d located between ferrite

Fig. 13 SEM images showing sample morphology with a schematic representation of sample cutting wear: a and c IA700; b and d IA750

Fig. 14 TEM images showing sample cracks, and a schematic representation of fatigue wear: a-c IA700, d-f IA750

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