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Abstract
The influence of pulse impact on the microstructure and properties of welded joints of aluminium matrix composite SiCp/AlSi7Mg by liquid phase pulse impact diffusion welding (LPPIDW) and its welding mechanism had been studied. It showed that during LPPIDW, under the effect of pulse impact, the interface state between SiC particle and matrix was prominent, the initial pernicious contact state of reinforcement particles had been changed from reinforcement (SiC)/reinforcement (SiC) to reinforcement (SiC)/matrix/reinforcement (SiC), and the harmful microstructure or brittle phase was restrained from the welded joint. Moreover, the density of dislocation in the matrix neighbouring to and away from the interface was higher than that of its parent composite and the dislocation entwisted each other intensively. Furthermore, the deformation mainly occurred in the matrix grain and the matrices around SiC particles engendering intensive aberration offered a high density nucleus area for matrix crystal in favour of forming nanograins, which improved the properties of welded joints distinctly, resulting in welding the composite successfully. Consequently, the tensile strength of the welded joints was up to 179 MPa, which was ∼74˙6% of the strength of SiCp/AlSi7Mg (as stir cast), and its corresponding radial deformation was less than 3%, suitable for the demand of deformation of welded specimens.