Effects of Coefficient of Thermal Expansion and Moisture Absorption on the Dimensional Accuracy of Carbon-Reinforced 3D Printed Parts

Environmental effects-temperature and moisture-on 3D printed part dimensional accuracy are explored. The coefficient of thermal expansion of four different nylon materials was determined for XY and ZX print orientations, with 0 & DEG;, 45 & DEG;/-45 & DEG;, and 90 & DEG; infill patterns. Unreinforced nylon exhibited a thermal expansion coefficient of the same order regardless of condition (from 11.4 to 17.5 x 10(-5) 1/& DEG;C), while nylons reinforced with discontinuous carbon fiber were highly anisotropic, for instance exhibiting 2.2 x 10(-5) 1/& DEG;C in the flow direction (0 & DEG; infill angle) and 24.8 x 10(-5) 1/& DEG;C in the ZX orientation. The temperature profile of a part during printing is shown, demonstrating a build steady state temperature of ~ 35 & DEG;C. The effect of moisture uptake by the part was also explored, with dimensional changes of ~0.5-1.5% seen depending on feature, with height expanding the most. The effects of moisture were significantly reduced for large flat parts with the inclusion of continuous fiber reinforcement throughout the part.