Optimization of process parameters to minimize circularity error and surface roughness in fused deposition modelling (FDM) using Taguchi method for biomedical implant fabrication

Abstract

Fused Deposition Modeling (FDM) has emerged as a pivotal additive manufacturing technology that enables the creation of complex geometries with high precision and repeatability, particularly in the fabrication of biomedical implants. The functional additive manufacturing components, such as custom prosthetics, dental implants, and surgical guides, are expected to have dimensional accuracy and superior surface finish to ensure biocompatibility, osseointegration, and optimal tissue-implant interaction. This study aimed to optimize the FDM process parameters to minimize circularity error and surface roughness (Ra) using the Taguchi method, with a focus on biomedical implant fabrication. The printing temperature, printing speed, and layer thickness were identified as significant factors affecting circularity and Ra. Orthogonal arrays of Taguchi L9 were devised with three levels of each factor. Circularity and Ra were measured on the printed specimens, which included biomedical implant prototypes. The signal-to-noise (S/N) ratio response analysis determined the optimal parameter combinations. Results showed that the most dominant factor for circularity error reduction was build orientation, while layer thickness had the highest influence on Ra. The confirmation runs validated that the Taguchi-optimized parameters reduced the circularity error by 42% and Ra by 67% compared to default settings. Therefore, the Taguchi method proved effective in identifying the ideal process combinations for biomedical implant fabrication. The findings can help FDM users in the biomedical sector minimize dimensional errors and improve surface finish quality, ultimately enhancing the performance and reliability of medical implants.