Integrated Experimental and Machine Learning-Based Predictive Analysis of FDM Parameters for Conductive PLA-Based Composites

dc.contributor.authorAltuncu, Mehmet Ali
dc.contributor.authorUlkir, Osman
dc.contributor.authorKuncan, Melih
dc.date.accessioned2026-07-13T12:18:24Z
dc.date.issued2026
dc.departmentMuş Alparslan Üniversitesi
dc.description.abstractThis study investigates the effects of fused deposition modeling (FDM) parameters on the tensile strength and electrical conductivity of conductive polylactic acid (PLA)-based composites. An integrated experimental and machine learning (ML)-based framework was used. Printing speed (PS), infill density (ID), layer thickness (LT), and nozzle temperature (NT) were determined as printing parameters. A full factorial design was employed, yielding 81 unique parameter combinations. Experimental results showed that both tensile strength and electrical conductivity were affected by the selected printing parameters. Tensile strength ranged from 16.44 to 49.14 MPa, and electrical conductivity ranged from 0.01332 to 0.10442 S/cm. Overall, lower speed, higher density, lower thickness, and higher temperature improved performance. Analysis of variance (ANOVA) revealed that ID and LT were the most influential factors, with statistically significant effects (p < 0.05) for both response variables. ML models were developed to establish predictive relationships between printing parameters and output responses. For this purpose, a random forest (RF), k-nearest neighbors (KNN), and deep kernel learning (DKL) inspired model were trained and evaluated using five-fold cross-validation. For tensile strength estimation, the RF and KNN models achieved R-2 values of 0.8582 and 0.8899, respectively, while the DKL-inspired model provided the highest accuracy with R-2 = 0.9999. Similarly, for electrical conductivity estimation, the RF and KNN models produced R-2 values of 0.9001 and 0.8810, respectively, while the DKL-inspired model again showed the best performance with R-2 = 0.9999. Sample-based error analysis further confirmed the superiority of the DKL-inspired model. For this model, the mean percentage error was 0.14% for tensile strength and 0.28% for electrical conductivity. The results demonstrate that the combined use of experimental design, statistical analysis, and ML provides an effective approach to understanding the multifunctional performance of FDM printed conductive PLA-based composites.
dc.identifier.doi10.1002/pat.70626
dc.identifier.issn1042-7147
dc.identifier.issn1099-1581
dc.identifier.issue5
dc.identifier.scopus2-s2.0-105038814219
dc.identifier.scopusqualityQ2
dc.identifier.urihttps://doi.org/10.1002/pat.70626
dc.identifier.urihttps://hdl.handle.net/20.500.12639/8913
dc.identifier.volume37
dc.identifier.wosWOS:001766813000001
dc.identifier.wosqualityQ2
dc.indekslendigikaynakWeb of Science
dc.indekslendigikaynakScopus
dc.language.isoen
dc.publisherWiley
dc.relation.ispartofPolymers for Advanced Technologies
dc.relation.publicationcategoryMakale - Uluslararası Hakemli Dergi - Kurum Öğretim Elemanı
dc.rightsinfo:eu-repo/semantics/openAccess
dc.snmzKA_WOS_20250701
dc.subjectConductive Polylactic Acid
dc.subjectConductivity
dc.subjectDeep Kernel Learning
dc.subjectFused Deposition Modeling
dc.subjectMachine Learning
dc.titleIntegrated Experimental and Machine Learning-Based Predictive Analysis of FDM Parameters for Conductive PLA-Based Composites
dc.typeArticle

Dosyalar