Investigations and predictions for mechanical and surface properties of FFF prints using DOE, ML and FEA

ABSTRACT

In the past two decades, number of studies have been reported on process parametric optimisation of the fused filament fabrication (FFF) process for polylactic acid-based functional prototypes by using design of experiment techniques. But hitherto little has been reported on the prediction of mechanical and surface properties of FFF prints using machine learning (ML) and a finite element analysis (FEA) approach. The present research work aims to provide insight into the influence of FFF parameters, namely: layer thickness (LT), infill structure (IS) and infill density (ID) on Young’s modulus and surface roughness. In the first stage, optimum process parameters of FFF for Young’s modulus and surface roughness have been evaluated as 0.16 mm LT, cubic IS and 45% ID along with an analysis of variance-based linear models. The ML-based computational model has been developed to predict and verify the experimental observations in the second stage. Finally, in the third stage, experimental and predicted values of Young’s modulus have been co-related based upon FEA (by using ABAQUS software).

KEYWORDS:

• Additive manufacturing
• fused deposition modelling
• finite element analysis
• machine learning
• mechanical properties
• slicing parameters

Acknowledgement

The authors are thankful to NITTTR Chandigarh for providing experimental facilities.

Disclosure statement

No potential conflict of interest was reported by the authors.