Characterization and Testing of Copper-Nickel Electroplated 3D Printed Parts for Space Flight Applications

3D printing enables novel designs which are impossible to replicate with conventional machining. The process involves 3D printing components from a polymer using a standard resin-based printing process, then electroplating the parts with a thin layer of copper-nickel. Initial results have shown these electroplated components have increased structural strength, while being less expensive; less massive; and can be made faster compared to conventional CNC machining. The focus and metric of success was to qualify this process and to answer the question if the 3D printed electroplated parts can be fabricated in a more cost, mass and schedule efficient manor compared to traditional CNC machining. Also, to determine if using this method will cause parts to have contamination issues or if parts can survive space environment testing. This was accomplished by conducting several critical tests such as outgassing, material testing and thermal cycling. In addition, this method is being used to develop a practical structural application for KArLE (Potassium Argon Laser Experiment).