Dynamic Compressive Property of Closed-Cell Mg Alloy Composite Foams Reinforced with SiC Particles

doi:10.1007/s40195-019-00908-0

Abstract

Abstract:

The high-strain-rate mechanical response of Mg alloy/SiC_p composite foams has received increased attention in recent years due to their light weight and potential to absorb large amounts of energy during deformation. Dynamic compressive properties of closed-cell Mg alloy/SiC_p composite foams with different relative densities (0.162, 0.227 and 0.351) and different SiC_p additions (0, 4 and 8 wt%) have been investigated using Split-Hopkinson pressure bar. It is shown that peak stress and energy absorption capacity significantly increase as the relative density increases at the range of testing strain rates. Peak stress and energy absorption display strain rate dependence. The peak stress of specimens with 0 wt% and 4 wt% SiC particles additions grows with increasing strain rate. Meanwhile, the increment in the peak stress of specimens with 8 wt% addition is not significant with strain rate increasing. The increase in strain rate increases the energy absorption capacity. The suitable amount of SiC particles addition has great advantages over increasing the peak stress and energy absorption capacity at the high strain rate. The strain-rate-sensitive matrix, cell morphology, morphological defects and gas pressure have an impact on the strain-rate sensitivity of Mg alloy/SiC_p composite foams.

Key words: Mg alloy, SiC particles Mg alloy/SiC_p composite foam, Split-Hopkinson pressure bar system (SHPB), Dynamic compressive

Wen-Zhan Huang, Hong-Jie Luo, Yong-Liang Mu, Jian-Rong Xu, Ai-Chun Zhao. Dynamic Compressive Property of Closed-Cell Mg Alloy Composite Foams Reinforced with SiC Particles[J]. Acta Metallurgica Sinica (English Letters), 2019, 32(11): 1320-1328.

Figures/Tables 9

Fig. 1 Macrostructure and microstructure of closed-cell Mg alloy/SiCp composite foams with 4 wt% SiCp: a the present closed-cell foam with a relative density of 0.227, b, c distribution of SiCp in the cell wall of foams

Fig. 2 Dynamic compressive stress-strain response of Mg alloy/SiCp composite foam with different relative densities: a 0.162, b 0.227, c 0.351

Fig. 3 Peak stress against strain rates at different relative densities

Fig. 4 Energy absorption capacity of Mg alloy/SiCp composite foams versus strain rates with the relative densities of 0.162, 0.227 and 0.351, respectively

Fig. 5 Dynamic compressive stress-strain response of Mg alloy/SiCp composite foam with different SiCp additions: a 0 wt%, b 4 wt%, c 8 wt%

Fig. 6 Variation in the peak stress of specimens with different SiCp additions with increasing strain rates

Fig. 7 Energy absorption capacity of Mg alloy/SiCp composite foams versus strain rates with different SiCp additions

Fig. 8 Dynamic compressive final morphologies of Mg alloy/SiCp composite foams with 8 wt% SiCp with different strain rates

Fig. 9 SEM image of the fracture surfaces in the fragments of the Mg alloy/SiCp composite foams after the dynamic compression: a cracks in the cell walls, b-d the fracture and collapse of the cell wall. (Note: arrows indicate the cell edge, the boxed-in area of the figure (d) is plateau border)

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