Litcius/Paper detail

Evaluation of effect and optimizing of process parameters for fused deposition modeling parts on tensile properties via Taguchi method

Sermet Demir, Caner Yüksel

2022Rapid Prototyping Journal21 citationsDOI

Abstract

Purpose The purpose of this paper is to analyze the effect of printing parameters on the mechanical properties of standard dog bone specimens manufactured by fused deposition modeling. Design/methodology/approach Polylactic acid (PLA) specimens were printed and tested according to the ASTM standard. The effect of five important printing parameters, layer height, raster angle, printing speed, nozzle temperature and nozzle diameter, was examined on ultimate tensile strength (UTS), elongation and apparent density. Five levels were attended for each parameter, and a high number of required experiments were reduced by applying the L 25 Taguchi design of the experiment. Findings The effect of each parameter on outputs and optimal values for maximum tensile strength were determined. The most influential parameter is the raster angle of 64.96%. Nozzle temperature has a low effect of 1.76%, but nozzle diameter contribution is 9.77%. The experiment results are validated by analysis of variance analysis, and the optimal predicted level for parameters is 90° raster angle, 0.2 mm layer height, 100 mm/s printing speed, 200°C nozzle temperature and 0.8 mm nozzle diameter. The maximum UTS observed is 48.70 MPa for 0.8 mm nozzle diameter, whereas the minimum is 18.49 for 0.2 mm nozzle diameter. Originality/value This paper is a very extensive experimental research report on the effect of the parameters for the tensile property of 3D printed PLA specimens by the Taguchi method. The documented results can be further developed for an optimization model to obtain a desired mechanical property with less variation and uncertainty in a product.

Topics & Concepts

Taguchi methodsNozzleUltimate tensile strengthMaterials scienceFused deposition modelingComposite materialOrthogonal arrayDesign of experimentsRaster graphicsDeposition (geology)Process variableStructural engineering3D printingMechanical engineeringProcess (computing)Computer scienceMathematicsEngineeringBiologySedimentStatisticsArtificial intelligenceOperating systemPaleontologyAdditive Manufacturing and 3D Printing TechnologiesAdditive Manufacturing Materials and Processes3D Printing in Biomedical Research
Evaluation of effect and optimizing of process parameters for fused deposition modeling parts on tensile properties via Taguchi method | Litcius