Abstract
The nitridation-induced self-formed aluminum matrix composite (NISFAC) process is based on the nitridation reaction, which can be significantly influenced by the characteristics of the starting materials (e.g., the chemical composition of the aluminum powder and the type, size, and volume fraction of the ceramic reinforcement) and the processing variables (e.g., process temperature and time, and flow rate of nitrogen gas). Since these variables do not independently affect the nitridation behavior, a systematic study is necessary to examine the combined effect of these variables upon nitridation. In this second part of our two-part report, we examine the effect of nitrogen flow rates and processing temperatures upon the degree of nitridation which, in turn, determines the amount of exothermic reaction and the amount of molten Al in the nitridation-induced self-formed aluminum matrix composite (NISFAC) process. When either the nitrogen flow rate or the set temperature was too low, high-quality composites were not obtained because the level of nitridation was insufficient to fill the powder voids with molten Al. Hence, since the filling of the voids in the powder bed by molten Al is essential to the NISFAC process, the conditions should be optimized by manipulating the nitrogen flow rate and processing temperature.
Highlights
We recently developed the nitridation-induced self-formed aluminum composite (NISFAC)process as a facile and innovative route to manufacturing Al matrix composites (AMCs) [1,2,3]
The amount of molten Al is determined by the degree of nitridation, which can be controlled by the various process parameters
We have reported the effects of process parameters upon the fabrication of Al 6061/SiC
Summary
We recently developed the nitridation-induced self-formed aluminum composite (NISFAC)process as a facile and innovative route to manufacturing Al matrix composites (AMCs) [1,2,3]. Materials 2020, 13, 1213 resulting in AMCs. Materials 2020, 13, 1213 resulting in AMCs This suggests that the properties of the obtained AMCs can be freely tailored by manipulating the type, size, and volume fraction of the reinforcement to generate a number of combinations comparable with those available in alloy design. This suggests that AMCs with identical properties can be produced with different combinations of Al matrix and reinforcement (or filler). The number of applicable AMCs can be greatly increased, thereby contributing to the expansion of end-user choice
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