Abstract
We have investigated the basic characteristics of C/Al composites prepared in-process via selective laser melting (SLM) using a mixed powder of pure aluminum and short carbon fiber. Initially, the relationship between the relative density of the SLM composites and laser scan conditions was systematically investigated. The SLM composites were densified by applying laser scan conditions with high input energy density (>100 J/mm3). The densified SLM composite showed excellent hardness together with low thermal conductivity, due to the generation of an Al4C3 phase and increased solid-solution carbon in the α-Al matrix via the reaction between aluminum and carbon during laser irradiation. This reaction could be inhibited in SLM composites fabricated from another mixed powder of copper-plated carbon fiber and pure aluminum powder since laser absorptivity significantly decreased due to the high reflectivity of the copper plate on the carbon fiber. By investigating the Cu plated C/Al SLM composites, we demonstrated that the thermal management material having anisotropic thermal conductivity could be fabricated by controlling the carbon dispersion by using a unidirectional laser scanning pattern.
Highlights
Additive manufacturing (AM) is a layer-by-layer production method, which has garnered attention as a manufacturing technology for the production of complicated parts [1,2]
By taking advantage of its free design feature, innovative parts with novel and/or excellent functions have been developed in various fields including the aerospace, automotive and machinery industries [3,4]
Selective laser melting (SLM) is one of the metal AM processes based on powder-bed fusion [5,6]
Summary
Additive manufacturing (AM) is a layer-by-layer production method, which has garnered attention as a manufacturing technology for the production of complicated parts [1,2]. Previous studies revealed that Al SLM materials consisting of casting alloys, such as AlSi10Mg [9,10,11,12,13], AlSi7Mg0.3 [14,15], and AlSi12 [16], had distinctive characteristics of extremely fine microstructures in the sub-micron size. This was due to the rapid cooling by laser irradiation, which was estimated to be 105–106 K/s by Li and Gu [17] and
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