Abstract
Powder bed fusion of thermoplastic polymers is a powder based additive manufacturing process that allows for manufacturing individualized components with high geometric freedom. Despite achieving higher mechanical properties compared to other additive manufacturing processes, statistical variations in part properties and the occurrence of defects cannot be avoided systematically. In this paper, a novel method for the inline assessment of part porosity is proposed in order to detect and to compensate for inherent limitations in the reproducibility of manufactured parts. The proposed approach is based on monitoring the parameter-specific decay of the optical melt pool radiance during the melting process, influenced by a time dependency of optical scattering within the melt pool. The underlying methodology compromises the regression of the time-dependent optical melt pool properties, assessed in visible light using conventional camera technology, and the resulting part properties by means of artificial neural networks. By applying deep residual neural networks for correlating time-resolved optical process properties and the corresponding part porosity, an inline assessment of the spatially resolved part porosity can be achieved. The authors demonstrate the suitability of the proposed approach for the inline porosity assessment of varying part geometries, processing parameters, and material aging states, using Polyamide 12. Consequently, the approach represents a methodological foundation for novel monitoring solutions, the enhanced understanding of parameter–material interactions and the inline-development of novel material systems in powder bed fusion of polymers.
Highlights
Laser-based powder bed fusion of polymers (PBF-LB/P) is a powder-based additive manufacturing process of polymer components that is subject to a variety of process influences
The time-resolved evolution is characterized by the convergence towards a process-specific level of the relative radiance, referred to as the normalized radiance of visible light detected for a particular area, is applied as the under‐ lying metric for quantifying the time‐dependency of optical properties of the melt pool
PBF of Polyamide 12 can be characterized by a time dependency of optical melt pool prop‐
Summary
Laser-based powder bed fusion of polymers (PBF-LB/P) is a powder-based additive manufacturing process of polymer components that is subject to a variety of process influences. These include exposure parameters [1], varying geometries [2], and physical as well as chemical properties of the applied material [3]. To overcome the issue of a limited understanding of the relations between part properties and the underlying process, the monitoring and subsequent modeling of these aspects constitutes a critical factor for enhancing the reproducibility of PBF-LB/P. Deep artificial neural networks represent a possibility to model the complex relations between process properties and the resulting part properties in PBF-LB/P
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