Effects of Reheating Duration on the Microstructures and Tensile Properties of Thixoforged In Situ Mg2Sip/AM60B Composites

doi:10.1007/s40195-014-0159-7

Abstract

Abstract:

The influences of reheating duration on microstructures and tensile properties of thixoforged in situ Mg₂Si_p/AM60B composites have been investigated. The results indicate that the reheating time affects the volume fraction, composition and distribution of the liquid phase, the evolution of the liquid pools within the primary particles, and the morphology and distribution of the Mg₂Si particles of the semisolid feedstock. These changes then affect the subsequent solidification behavior and deformation mechanism during thixoforging, which are responsible for the resulting microstructure and tensile properties. Mg₂Si particles play a strengthening role for the matrix through the load transfer mechanism. The appropriate reheating time is 60 min at 600°C when the mold preheating temperature is at 300°C. The ultimate tensile strength and elongation of the resulting composite are up to 209 MPa and 11.9%, respectively.

Key words: In situ synthesis, Magnesium matrix composites, Semisolid, Mechanical properties

Chen Tijun, Zhang Suqing, Chen Yushi, Li Yuandong, Ma Ying, Hao Yuan. Effects of Reheating Duration on the Microstructures and Tensile Properties of Thixoforged In Situ Mg₂Si_p/AM60B Composites[J]. Acta Metallurgica Sinica (English Letters), 2014, 27(5): 957-967.

Figures/Tables 13

Fig. 1 Schematic of the tensile testing specimen

Fig. 2 OM image a and SEM image b showing the microstructure of the as-cast composite, and OM images showing the semisolid microstructures at the edge c and center d regions of the ingot (heated for 60 min at 600°C)

Fig. 3 Temperature variation in the center of the ingot with heating time at 600°C

Fig. 4 OM micrographs of the in situ Mg2Sip/AM60B composites thixoforged under heating for different durations at 600°C: a center region, 50 min; b edge region, 50 min; c center region, 60 min; d edge region, 60 min; e center region, 70 min; f edge region, 70 min; g center region, 90 min; h edge region, 90 min; i center region, 120 min; j edge region, 120 min

Table 1 Compositions of the primary particles in the in situ Mg2Sip/AM60B composites thixoforged under different reheating durations at 600°C (in wt%)

Reheating duration (min)	Al	Mg
50	4.4	95.6
60	5.3	94.7
70	5.8	94.2
90	4.8	95.2
120	4.9	95.1

Fig. 5 SEM images in the center regions of the composites thixoforged under reheating at 600°C for 50 min a, 60 min b, 70 min c, 90 min d

Fig. 6 Variation of the β phase amount with reheating duration

Fig. 7 OM images of the center regions of the composites thixoforged under reheating for 50 min a, 60 min b, 70 min c, 90 min d, 120 min e

Fig. 8 OM micrographs of the composites thixoforged under reheating for different durations and then solution treated for 1 h at 430°C: a 50 min; b 60 min; c 70 min; d 90 min; e 120 min

Fig. 9 Variations of UTS and elongation with reheating duration

Fig. 10 Fractographs of composites thixoforged under different reheating durations at 600°C: a 50 min; b 60 min; c 70 min; d 90 min; e 120 min

Fig. 11 Side views of composite fracture surfaces thixoforged under different reheating durations at 600°C: a 50 min; b 60 min; c 70 min; d 90 min; e 120 min

Fig. 12 Typical fractographs and fracture surface side views of the composites: a fragmented Mg2Si particles; b side view of fragmented Mg2Si particle of the composite thixoforged under reheating for 60 min; c Mg2Si/matrix interface debonding of the composite thixoforged under reheating for 70 min; d Mg2Si clusters in the composite thixoforged under reheating for 120 min

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Effects of Reheating Duration on the Microstructures and Tensile Properties of Thixoforged In Situ Mg₂Si_p/AM60B Composites

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