On the Microstructural Strengthening and Toughening of Heat-Affected Zone in a Low-Carbon High-Strength Cu-Bearing Steel

doi:10.1007/s40195-020-01159-0

Abstract

Abstract:

In this article, the influence of simulated thermal cycles for the heat-affected zone (HAZ) on the microstructural evolution and mechanical properties in a low-carbon high-strength Cu-bearing steel was investigated by microstructural characterization and mechanical tests. The results showed that the microstructure of the coarse-grained heat-affected zone (CGHAZ) and the fine-grained heat-affected zone (FGHAZ) was mainly comprised of lath martensite, and a mixed microstructure consisting of intercritical ferrite, tempered martensite and retained austenite occurred in the intercritically heat-affected zone (ICHAZ) and the subcritically heat-affected zone (SCHAZ). Also, 8-11% retained austenite and more or less Cu precipitates were observed in the simulated HAZs except for CGHAZ. Charpy impact test indicated that the optimum toughness was obtained in FGHAZ, which was not only associated with grain refinement, but also correlated with deformation-induced transformation of the retained austenite, variant configuration as interleaved type and a relatively weak variant selection. The toughness of ICHAZ and SCHAZ exhibited a slight downtrend due to the presence of Cu precipitates. The CGHAZ has the lowest toughness in the simulated HAZs, which was attributed to grain coarsening and heavy variant selection. In addition, the contribution of Cu precipitates to yield strength in simulated HAZs was estimated based on Russell-Brown model. It demonstrated an inverse variation trend to toughness.

Key words: Low-carbon high-strength steel, Heat-affected zone, Cu addition, Toughness, Precipitation strengthening

Xiaohui Xi, Jinliang Wang, Liqing Chen, Zhaodong Wang. On the Microstructural Strengthening and Toughening of Heat-Affected Zone in a Low-Carbon High-Strength Cu-Bearing Steel[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(5): 617-627.

Figures/Tables 14

Fig. 1 Diagram of welding thermal simulation for different reheated HAZs

Fig. 2 Dilatometry data for base steel heated to various peak temperatures: a martensite volume, b relative length changes as a function of temperature on cooling

Fig. 3 Microstructural evolution for the simulated HAZs: a CGHAZ, b FGHAZ, c ICHAZ, d SCHAZ, e base steel (M: martensite, IF: intercritical ferrite, RA: retained austenite)

Fig. 4 XRD spectra and volume percentage of retained austenite for the simulated HAZs

Fig. 5 EBSD images showing different martensite substructures: a CGHAZ, b FGHAZ, c ICHAZ, d SCHAZ, e base steel

Fig. 6 Inverse pole figure (IPF) of the prior austenite grain of the simulated HAZs: a CGHAZ, b FGHAZ, c ICHAZ, d SCHAZ, e density of high-angle grain boundary with misorientation > 45°

Fig. 7 {100} Pole figure showing orientation distribution of the simulated HAZs corresponding to IPF in Fig. 6: a CGHAZ, b FGHAZ, c ICHAZ, d SCHAZ

Fig. 8 TEM images showing the precipitation distribution in the simulated HAZs: a CGHAZ, b FGHAZ, c ICHAZ, d SCHAZ, e base steel, f energy-dispersive spectroscopy (EDS) of Cu precipitates

Fig. 9 Charpy impact energy of the simulated HAZs

Fig. 10 SEM fractographs of the simulated HAZs: a CGHAZ, b FGHAZ, c ICHAZ, d SCHAZ

Fig. 11 Measured Vickers microhardness as a function of peak temperature for the simulated HAZs

Table 1 Parameters used in Russell-Brown model [31]

G	b	R	r₀	${E}_{\mathrm{P}}^{\infty }/{E}_{\mathrm{M}}^{\infty }$
77 GPa	0.25 nm	1000 r₀	1.2 nm	0.6

Table 2 Interprecipitate spacing (L) and average radius (r) for the simulated HAZs

	CGHAZ	FGHAZ	ICHAZ	SCHAZ	Base steel
L (nm)	-	57.5	51.0	60.8	58.4
r (nm)	-	6.8	8.5	17.2	12.6

Fig. 12 Predicted strength increment due to Cu precipitation

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