Abstract
Additive manufacturing technologies present a series of advantages such as high flexibility, direct CAD to final product fabrication, and compact production techniques which make them an attractive option for fields ranging from medicine and aeronautics to rapid prototyping and Industry 4.0 concepts. However, additive manufacturing also presents a series of disadvantages, the most notable being low dimensional accuracy, low surface quality, and orthotropic mechanical behaviour. These characteristics are influenced by material properties and the process parameters used during manufacturing. Therefore, a predictive model for the characteristics of additive manufactured components is conceivable. This paper proposes a study on the feasibility of implementing Deep Neural Networks for predicting the dimensional accuracy and the mechanical characteristics of components obtained through the Fused Deposition Modelling method using empirical data acquired by high precision metrology. The study is performed on parts manufactured using PETG and PLA materials with known process parameters. Different Deep Neural Network architectures are trained using datasets acquired by high precision metrology, and their performance is tested by comparing the mean absolute error of predictions on training and validation data. Results show good model generalisation and convergence at high accuracy, indicating that a predictive model is feasible.
Highlights
Published: 11 February 2022Additive manufacturing technologies are becoming an essential tool in a wide variety of fields ranging from medicine and aeronautics to industry 4.0 concepts, rapid prototyping, reverse engineering, and hobby use
The study presented in this paper aims to determine the ability of artificial neural networks to learn and approximate the complex functions needed to predict dimensional deviations and mechanical behaviour of parts obtained by the FusedDeposition Modelling (FDM) process using the main process parameters as well as material properties as inputs and empirical data obtained from high precision metrology and tensile strength measurements as outputs
The results show that artificial neural networks are capable of learning complex predictive functions for the quality of FDM manufactured parts, encouraging and informing future work in the field
Summary
Additive manufacturing technologies are becoming an essential tool in a wide variety of fields ranging from medicine and aeronautics to industry 4.0 concepts, rapid prototyping, reverse engineering, and hobby use. This rapid increase in the exploitation of additive manufacturing techniques is a direct result of the many advantages presented by these technologies, which include high flexibility, low cost, direct computer-aided design (CAD). Due to the low cost of the machines and materials, the FDM technique is becoming important for rapid prototyping, hobby use, manufacturing of replacement parts, and even as a supplement for the more productive technologies such as Injection.
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