Analysis and Optimization of Dimensional Accuracy and Porosity of High Impact Polystyrene Material Printed by FDM Process: PSO, JAYA, Rao, and Bald Eagle Search Algorithms.

Manjunath Patel Gowdru Chandrashekarappa,Danil Yurievich Pimenov,Balakrishnamurthy Sachin Kumar,Khaled Giasin,Szymon Wojciechowski,Ganesh Ravi Chate,Annan Kaisar,Mohd Amaan Najeeb Bandukwala,Vineeth Parashivamurthy

doi:10.3390/ma14237479

Abstract

High impact polystyrene (HIPS) material is widely used for low-strength structural applications. To ensure proper function, dimensional accuracy and porosity are at the forefront of industrial relevance. The dimensional accuracy cylindricity error (CE) and porosity of printed parts are influenced mainly by the control variables (layer thickness, shell thickness, infill density, print speed of the fused deposition modeling (FDM) process). In this study, a central composite design (CCD) matrix was used to perform experiments and analyze the complete insight information of the process (control variables influence on CE and porosity of FDM parts). Shell thickness for CE and infill density for porosity were identified as the most significant factors. Layer thickness interaction with shell thickness, infill density (except for CE), and print speed were found to be significant for both outputs. The interaction factors, i.e., shell thickness and infill density, were insignificant (negligible effect) for both outputs. The models developed produced a better fit for regression with an R2 equal to 94.56% for CE, and 99.10% for porosity, respectively. Four algorithms (bald eagle search optimization (BES), particle swarm optimization (PSO), RAO-3, and JAYA) were applied to determine optimal FDM conditions while examining six case studies (sets of weights assigned for porosity and CE) focused on minimizing both CE and porosity. BES and RAO-3 algorithms determined optimal conditions (layer thickness: 0.22 mm; shell thickness: 2 mm; infill density: 100%; print speed: 30 mm/s) at a reduced computation time equal to 0.007 s, differing from JAYA and PSO, which resulted in an experimental CE of 0.1215 mm and 2.5% of porosity in printed parts. Consequently, BES and RAO-3 algorithms are efficient tools for the optimization of FDM parts.

Highlights

Effective waste management in fabricating parts to desired shapes at low cost led to the development of 3-D printing technology, called additive manufacturing (AM) [1].Industry 4.0 aims at developing extremely high material, efficiency-based AM processing routes for industrial-scale production of parts [2]
High Impact Polystyrene (HIPS) material is widely applied for developing prototypes and low-strength structural applications due to its economic and technical benefits [29,30]
The responsewise analysis was performed to determine detailed insight regarding the influence of input variables

Summary

Introduction

Effective waste management in fabricating parts to desired shapes at low cost led to the development of 3-D printing technology, called additive manufacturing (AM) [1].Industry 4.0 aims at developing extremely high material, efficiency-based AM processing routes for industrial-scale production of parts [2]. Effective waste management in fabricating parts to desired shapes at low cost led to the development of 3-D printing technology, called additive manufacturing (AM) [1]. The 3D printing technique is popular for fabricating simple or custom-designed parts on a small scale [3]. AM techniques do not require high-cost molds to fabricate parts. AM techniques are thereby applied to fabricate parts useful for aerospace, civil, biomedical, surgical implants, automobiles, electronics, and so on [5,6]. This has led to rapid progress in the global market with an estimated increased rate of ≈17% compound annual growth rate [3]

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Results

Conclusion