A Hot Cracking Initiation Criterion Based on Solidification Liquid Film Characteristic and Microstructure

doi:10.1007/s40195-023-01598-5

Abstract

Abstract:

Herein, a hot cracking initiation criterion based on the characteristics of solidification liquid film and the microstructure was proposed, which integrated both the mechanical and non-mechanical factors during solidification. The criterion also took the effect of the shrinkage volume of the solid-liquid two-phase in the mushy zone, the flow behavior of the liquid film and the microstructure on the feeding behavior into account. Meanwhile, the effect factors of hot cracking initiation such as alloy composition, microstructure, mold design and process condition were included in this criterion, and it could quantitatively calculate whether hot cracks occurred under a certain state or not during solidification. The criterion was utilized to predict whether hot cracks occurred in Al-4.0 wt% Cu alloy in different initial solidification states or not, which was consistent with the experimental results and verified its reliability. According to the criterion expression, V_feeding^* was related with five effect factors including η, ΔP^*, l^*, r^* and n, in which r^* and n were in positive correlation with V_feeding^* while η, ΔP^* and l^* were in negative correlation with that, which provided a good instructive significance for mold design, process optimization and composition and microstructure regulation of alloys and simultaneously further enriched the mechanism and influencing factors of hot cracking initiation. Furthermore, a multiscale simulation method for calculating the characteristic parameters of hot tearing behavior during solidification was also provided in this study.

Key words: Hot cracking criterion, Liquid film characteristic, Microstructure, Aluminum alloy, Multiscale simulation

Ming Su, Wentao Zheng, Chunyu Yue, Bowen Zheng, Xiaojiao Zuo, Mengyuan He, Xiaoguang Yuan. A Hot Cracking Initiation Criterion Based on Solidification Liquid Film Characteristic and Microstructure[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(11): 1776-1790.

Figures/Tables 14

Fig. 1 Schematic diagram of hot cracks: a initiation, b liquid film feeding process

Fig. 2 Schematic diagram of the derived model: a macroscopic scale, b microscopic scale

Fig. 3 Physical parameters of Al-4.0 wt% Cu alloy: a solidification path, b linear expansion coefficient α, c density ρ

Fig. 4 Microstructure and liquid film distribution in different initial solidification states at a 620 °C, b 630 °C, c 640 °C, and EPMA result of the liquid film d OM, e Al, f Cu

Fig. 5 a LFF, b l*, c r* of different initial solidification states

Fig. 6 Vs* of different experimental verification groups

Fig. 7 Calculation of Vl* a solidification diagram, b finite element model, c count maps of lP, d Vl* of different experimental verification group

Fig. 8 CFD model of the liquid film flow feeding

Fig. 9 Molecular dynamics simulation: a molecular dynamics calculation model, b η in different initial solidification states

Fig. 10 Parameters in different initial solidification states: a ΔP*, b Vfeeding*

Fig. 11 Vresidual* of Al-4.0 wt% Cu alloy in different initial solidification states

Table 1 Hot crack initiation temperatures in different initial solidification states

Solidification temperature (℃)	LFF (%)	Hot crack initiation temperature (℃)	Solidification temperature (℃)	LFF (%)	Hot crack initiation temperature (℃)	Solidification temperature (℃)	LFF (%)	Hot crack initiation temperature (℃)
620	11.37	593.52	630	12.73	588.74	640	16.39	570.28
620	11.85	585.92	630	16.84	582.24	640	17.27	564.31
620	15.13	578.63	630	18.84	573.40	640	19.13	560.00
620	15.79	576.09	630	18.89	566.11	640	19.39	555.38
620	17.28	571.31	630	20.82	561.64	640	33.76	549.84
620	21.17	569.32	630	25.73	556.05	640	36.68	No hot cracks

Fig. 12 Schematic diagram of the near-spherical grain feeding channel number in the three-dimensional space

Fig. 13 Hot cracking tendency of Al-4 wt% Cu alloys with different initial solidification states obtained by the RDG criterion and the Kou criterion

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