Abstract
Additive manufacturing of polymer powders is nowadays an industrial production technology. Complex thermal phenomena occur during processing, mainly related to the interaction dynamics among laser, powder, and heating system, and also to the subsequent cool-down phase from the melt to the parts. Thermal conductivity of the powder is a key property for material processing, since an inhomogeneous temperature field in the powder cake leads to uneven part properties and can strongly limit productivity because only a smaller portion of the build chamber can be used. Nevertheless, little is known about the relationship between thermal conductivity, packing density, and presence of fillers, which are used to enhance specific properties such as high temperature resistance or stiffness. The development and consequent validation of a device capable of measuring thermal conductivity as a function of powder packing density are then extremely important, providing an additional tool to characterize powders during the development process of new materials for PBF of polymers. The results showed a positive correlation between packing density and thermal conductivity for some commercially available materials, with an increase of the latter of about 10 to 40% with an increase of the packing density from 0 to 100%. Problems arose in trying to replicate the compaction state of the powder, since the same amount of taps led to a different packing density, but this is a known problem of measuring free-flowing powders such as the ones used for additive manufacturing. Regarding fillers, an increase of about 40 to 70% of thermal conductivity when inorganic fillers such as carbon fibers are added to the neat polymer was observed, and the expected behavior following the rule of mixture was only partially observed.
Highlights
Additive manufacturing (AM) is a family of manufacturing technologies for which an increasing interest is arising in different industries
The thermal conductivity of PA12 is in good agreement to what was reported by [11], the transient hot wire method used in this work is very different from the methodology used by the other authors
A more precise knowledge on the influence of compaction and presence of fillers on thermal conductivity of polymer powders is of fundamental importance for building more precise thermal models of the Powder bed fusion (PBF) process, and in general to improve the process robustness in industrial applications
Summary
Additive manufacturing (AM) is a family of manufacturing technologies for which an increasing interest is arising in different industries. Powder bed fusion (PBF) comprises most of AM with powder feedstock, and depending on the heating medium (lasers, IR lamps, etc.) and material (metal, polymer, or ceramic), it is named in different ways, the most common ones being laser sintering (LS, laser as heating medium, polymer as feedstock—official nomenclature PBF-LB/P) and selective laser melting (SLM, laser as power source, metal as feedstock—official nomenclature PBF-LB/M) [1, 2]. A laser beam scans the cross-section of the part on the build platform in order to selectively melt the polymer. This process is repeated for hundreds or thousands of layers, until the part is finished
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