This study adapts a melt extrusion module [1, 2], which was designed and developed by our group, selects Cu-base alloys capable of melting at <1300 oC, and has conducted 3D printing to make smart mold in previous study. Therefore, this research objectives are to investigate the hardness, wear resistance and compositional uniformity of Cu-based alloys, and the forces required for the melt extrusion. The results show that the hardness (269 HV) of annealed Cu-9Ni-6Sn is obviously superior to Cu-6Ni-2Al (237 HV) and the surface hardness (207 HV) of Ni-coated key. In contact wear, the higher the hardness of the alloys, the lower the wear rate. The relationship between hardness and wear rate is inversely linear behavior. A quantification analysis of the chemical composition of the wires used for 3D printing used Energy-dispersive X-ray spectroscopy (EDS) for the analysis. The standard deviation for the Ni in Cu-11Ni test is less than 0.2 %. Finally, the melting extrusion simulation of high temperature melt Cu alloy is conducted with 0.4 ~ 0.2 mm nozzle size. The required 4 forces against the frictions coming from the tube wall and the nozzle were considered. The simulation results resolve the flowing behavior of high viscous glass and melt Cu-alloy in Al2O3 nozzle through smaller nozzles.