Hot Deformation Behavior and Workability of (SiCp + Mg2B2O5w)/6061 Al Hybrid and SiCp/6061 Al Composites

doi:10.1007/s40195-014-0023-9

Abstract

Abstract:

The hot deformation behavior of (3 vol% SiC_p + 3 vol% Mg₂B₂O_5w)/6061 Al (W₃P₃) hybrid composite and 6 vol% SiC_p/6061 Al (P₆) composite have been characterized in the temperature range of 300–450 °C and strain rate range of 0.0001–0.1 s^-1 using isothermal constant true strain rate tests. The flow behavior and processing maps have been investigated using the corrected data to eliminate the effect of friction. Under the same deformation conditions, the compressive resistance of the singular composite remains superior to that of the hybrid composites. The processing map of W₃P₃ hybrid composite exhibits a single hot working domain at the temperature between 350 and 450 °C with strain rate between 0.0001 and 0.003 s^-1 (domain A). Two hot working domains exist for P₆ composite: (i) 300–400 °C/0.0001–0.003 s^-1 (domain B1); (ii) 380–450 °C/0.01–0.1 s^-1 (domain B2). The processing maps also reveal the flow instability of the two composites, which is associated with whiskers breakage, whisker/matrix interfacial debonding, SiC_p/matrix interfacial decohesion, adiabatic shear bands or flow localization, and wedge cracking in the corresponding regions. The estimated apparent activation energies are about 224 kJ mol^-1 in domain A for W₃P₃ hybrid composite, 177 kJ mol^-1 in domain B1 and 263 kJ mol^-1 in domain B2 for P₆ composite, respectively. These values are higher than that for self-diffusion in Al (142 kJ mol^-1), suggesting that there is a significant contribution from the back stress caused by the presence of particles and/or whiskers in the matrix. The deformation mechanisms corresponding to domain B1 and domain B2 are dislocation climb controlled creep and cross-slip for P₆ composite, respectively. For W₃P₃ hybrid composite, the deformation mechanisms contain dislocation climb controlled creep and grain boundary sliding caused by DRX in domain A.

Key words: Hybrid composite, Hot deformation, Processing map, Hot working, Kinetic analysis

Mingliang Wang, Peipeng Jin, Jinhui Wang, Li Han, Chuang Cui. Hot Deformation Behavior and Workability of (SiC_p + Mg₂B₂O_5w)/6061 Al Hybrid and SiC_p/6061 Al Composites[J]. Acta Metallurgica Sinica (English Letters), 2014, 27(1): 63-74.

Figures/Tables 18

Fig. 1 Microstructures of as-cast composites: a W3P3 hybrid specimen at low magnification (the whiskers of large size showing by arrows); b P6 specimen at low magnification; c W3P3 hybrid specimen at high magnification (the whiskers of large size showing by arrows); d P6 specimen at high magnification

Fig. 2 Micrographs showing reinforcement/matrix interfaces in as-cast microstructures: a whisker/matrix interface bonding for W3P3 hybrid composite; b SiCp/matrix interface bonding for W3P3 hybrid composite; c SiCp/matrix interface bonding for P6 composite

Fig. 3 Schematic drawing of hot compressed composites specimen

Fig. 4 Corrected true stress–strain curves for W3P3 hybrid composite (dotted lines) and P6 composite (solid lines) at different strain rates at different temperatures: a 300 °C, b 350 °C, c 400 °C, d 450 °C

Fig. 5 The corrected flow stress (at ε = 0.5) of the two composites as a function of \( { \lg }\,\dot{\varepsilon } \) at 300 and 450 °C

Fig. 6 Fitting curves to describe the relationship between lgσ and lg\( \dot{\varepsilon } \): a W3P3 hybrid composite; b P6 composite

Fig. 7 Processing map at the strain of 0.5 for W3P3 hybrid composite

Fig. 8 Processing map at the strain of 0.5 for P6 composite

Fig. 9 Micrograph clearly showing whisker breakage and whisker/matrix interfacial debonding (showing by arrows) deformed at 300 °C/0.0001 s-1 for W3P3 hybrid composite

Fig. 10 Micrographs showing a SiC particles structural intact and b SiCp/matrix interfacial bonding deformed at 300 °C/0.0001 s-1 for P6 composite

Fig. 11 Microstructures showing adiabatic shear bands or flow localization: a P6 composite deformed at 350 °C/0.1 s-1; b W3P3 hybrid composite deformed at 450 °C/0.1 s-1

Fig. 12 Micrographs showing reinforcement/matrix interfaces: a SiCp/matrix interface decohesion for P6 composite deformed at 350 °C/0.1 s-1; b whisker/matrix interface debonding for W3P3 hybrid composite deformed at 400 °C/0.1 s-1

Fig. 13 Higer magnification optical microstructure showing wedge crack deformed at 450 °C/0.0001 s-1 for P6 composite

Fig. 14 ln σ versus \( { \ln }\,\dot{\varepsilon } \) plots a and σ versus \( { \ln }\,\dot{\varepsilon } \) plots b at different temperatures for W3P3 hybrid composite

Fig. 15 ln σ versus \( { \ln }\,\dot{\varepsilon } \) plots a and σ versus \( { \ln }\,\dot{\varepsilon } \) plots b at different temperatures for P6 composite

Fig. 16 Variation of flow stress at the strain of 0.5 with strain rate at different test temperatures a and 1000/T versus ln (sinh (ασ)) plots at the strain of 0.5 at different strain rates for calculating activation energy for W3P3 hybrid composite b

Fig. 17 Variation of flow stress at the strain of 0.5 with strain rate at different test temperatures a and 1000/T versus ln (sinh (ασ)) plots at the strain of 0.5 at different strain rates for calculating activation energy for P6 composite b

Fig. 18 Apparent activation energies at the hot working domains for W3P3 hybrid and P6 composites

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Hot Deformation Behavior and Workability of (SiC_p + Mg₂B₂O_5w)/6061 Al Hybrid and SiC_p/6061 Al Composites

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