Litcius/Paper detail

T4F3: temperature for fused filament fabrication

Jie Zhang, Brecht Van Hooreweder, Eleonora Ferraris

2022Progress in Additive Manufacturing27 citationsDOIOpen Access PDF

Abstract

Abstract Temperature fields and their variations in printed parts are the basis for understanding the physical process of fused filament fabrication (FFF). However, reliable temperature data are still rather limited to date. This article presents a three-dimensional transient-state model to simulate the temporal and spatial temperature variations in FFF printed parts. Model variables range from geometry dimensions and (dynamic) material properties to process parameters, covering all important physical phenomena, including conduction anisotropy and radiant heat transfer. The validation of the model is performed against six sets of experimental temperature data obtained with different geometries, machines, materials, processes, temperature measuring methods, etc. Insights in the thermal process are also reported. For example, the heat penetration depth in printing with poly(lactic acid) is limited to 3 mm, and the Biot number intimately characterises the reheating peaks in temporal profiles. This model shows the potential to become a standardised tool to study the thermal characteristics of FFF printed parts. It is made openly available on website https://iiw.kuleuven.be/onderzoek/aml/technologyoffer . Graphic abstract

Topics & Concepts

Fused filament fabricationThermal conductionFabricationAnisotropyBiot numberThermalHeat transferMaterials scienceAtmospheric temperature rangeTransient (computer programming)Computer scienceMechanicsThermodynamicsPhysicsOptics3D printingComposite materialMedicinePathologyAlternative medicineOperating systemAdditive Manufacturing and 3D Printing TechnologiesInteractive and Immersive DisplaysAdvanced Sensor and Energy Harvesting Materials