Litcius/Paper detail

The influence of stiffener geometry on flexural properties of 3D printed polylactic acid (PLA) beams

Silas Z. Gebrehiwot, Leonardo Espinosa-Leal, J. N. Eickhoff, L. Rechenberg

2020Progress in Additive Manufacturing35 citationsDOIOpen Access PDF

Abstract

Abstract We used finite element analyses (FEA) on Abaqus to study flexural properties of additive manufactured beams using polylactic acid (PLA) polymer. Experimental stress–strain data from flexural testing are used to define elastic–plastic properties of the material in the computation software. The flexural experiments are used to validate the FEA approach suggested. The method provides good results of deflection and stress with errors well below 10% in most of the cases. Therefore, by using the proposed approach, costs related to repeated experimental works can be avoided. In addition, the flexural rigidities of the additive manufactured beams are studied. Five different beam stiffener designs (diamond, honeycomb, square, triangular and wiggle) are studied based on beam bending theory. The force–deflection data from the flexural tests are used to determine the area moments of inertia of the beams. The honeycomb stiffener showed the highest force–deflection behaviour that led to the highest calculated area moment of inertia. However, with the lowest force–deflection behaviour, the square stiffener had the lowest calculated area moment of inertia.

Topics & Concepts

Flexural strengthDeflection (physics)Polylactic acidStructural engineeringFlexural modulusThree point flexural testMaterials scienceFinite element methodComposite materialMoment of inertiaBeam (structure)Bending momentFlexural rigidityEngineeringPolymerPhysicsQuantum mechanicsOpticsAdditive Manufacturing and 3D Printing TechnologiesBone Tissue Engineering MaterialsInnovations in Concrete and Construction Materials