Abstract
Recently, with a broadening range of available materials and alteration of feeding processes, several extrusion-based 3D printing processes for metal materials have been developed. An emerging process is applicable for the fabrication of metal parts into electronics and composites. In this paper, some critical parameters of extrusion-based 3D printing processes were optimized by a series of experiments with a melting extrusion printer. The raw materials were copper powder and a thermoplastic organic binder system and the system included paraffin wax, low density polyethylene, and stearic acid (PW–LDPE–SA). The homogeneity and rheological behaviour of the raw materials, the strength of the green samples, and the hardness of the sintered samples were investigated. Moreover, the printing and sintering parameters were optimized with an orthogonal design method. The influence factors in regard to the ultimate tensile strength of the green samples can be described as follows: infill degree > raster angle > layer thickness. As for the sintering process, the major factor on hardness is sintering temperature, followed by holding time and heating rate. The highest hardness of the sintered samples was very close to the average hardness of commercially pure copper material. Generally, the extrusion-based printing process for producing metal materials is a promising strategy because it has some advantages over traditional approaches for cost, efficiency, and simplicity.
Highlights
With the rapid development of additive manufacturing (AM), metal AM has attracted more and more attention
We have demonstrated that metallic green samples can be produced through an extrusion-based printing process with the thermoplastic organic binder system
The raw materials with Cu particle content of 65 vol % can be prepared with the paraffin wax (PW)–low-density polyethylene (LDPE)–stearic acid (SA)
Summary
With the rapid development of additive manufacturing (AM), metal AM has attracted more and more attention. With a broadening range of available materials and alteration of feeding processes, several extrusion-based printing techniques for metal materials have been developed. FDMet is a modified FDM process, in which three-dimensional (3D) objects are built using metal filament fed into a heated extruder, but the fabrication of the fused filament has stringent requirements in the raw materials property and temperature control. Another newly developed process for metal materials is termed as 3D gel-printing (3DGP) [8]. The process comprises the following four steps: (1) mixing of the metal powder and organic binder to prepare raw materials;. (4) sintering to consolidate the debinding component This manufacturing method combines the traditional shape-making capability of the extrusion-based printing process and the material flexibility of powder metallurgy
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