Dental schools and dental laboratories can access entry-level Digital Light Processing (DLP) three-dimensional (3D) printers at low cost but are still not able to achieve print efficiency, dimensional accuracy and mechanical strength. This study aims to enhance these metrics of performance using multi-objective process parameter optimization for dental applications.
A Taguchi L16 (44) orthogonal array was used to evaluate four key parameters: layer height (0.02–0.1 mm), bottom layer count (4–10), exposure time (5–12.5 s) and bottom exposure time (20–35 s), with three replications per run. Gray Relational Analysis consolidated three performance metrics: building time, dimensional accuracy and compressive strength, into a single Gray Relational Grade. Dimensional deviation was analyzed using Python scripts in Jupyter Notebook to compare original and scanned STL files and CloudCompare software for visual alignment. Scanning was conducted with a MEDIT T310 scanner using Medit Scan for Labs software.
The optimal parameters were: layer height 0.02 mm, bottom layer count 4, exposure time 12.5 s and bottom exposure time 35 s. Experimental validation showed improvements in building time, dimensional accuracy and compressive strength. Analysis of variance determined layer height and exposure time as the most important parameters, contributing 43.79% and 38.92% to total variation, respectively, and bottom layer count and bottom exposure time contributing 9.43% and 6.78%.
The present research offers a structured multiresponse optimization method for enhancing the quality of dental parts produced with entry-level DLP 3D printers. It also highlights the practicable worth of statistical design of experiments in overcoming low-cost equipment restrictions, as well as ease of application in broader utilizations in clinics and academic institutions.
