Related papers: GraphCompNet: A Position-Aware Model for Predicting and Compensating Shape Deviations in 3D Printing

GraphCompNet: A Position-Aware Model for Predicting and Compensating Shape Deviations in 3D Printing

URL: http://arxiv.org/abs/2502.09652v2
Date: Mon, 17 Feb 2025 19:05:43 GMT
Title: GraphCompNet: A Position-Aware Model for Predicting and Compensating Shape Deviations in 3D Printing
Authors: Lei, Chen, Juheon Lee, Juan Carlos Catana, Tsegai Yhdego, Nathan Moroney, Mohammad Amin Nabian, Hui Wang, Jun Zeng,
Abstract summary: This paper introduces a data-driven algorithm for modeling and compensating shape deviations in additive manufacturing (AM) Recent advancements in machine learning (ML) have improved compensation precision, but issues remain in generalizing across complex geometries and adapting to position-dependent variations. We present a novel approach for powder bed fusion processes, using GraphCompNet, which is a computational framework combining graph-based neural networks with a generative adversarial network (GAN)-inspired training process.
Score: 46.76421610124468
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Abstract: This paper introduces a data-driven algorithm for modeling and compensating shape deviations in additive manufacturing (AM), addressing challenges in geometric accuracy and batch production. While traditional methods, such as analytical models and metrology, laid the groundwork for geometric precision, they are often impractical for large-scale production. Recent advancements in machine learning (ML) have improved compensation precision, but issues remain in generalizing across complex geometries and adapting to position-dependent variations. We present a novel approach for powder bed fusion (PBF) processes, using GraphCompNet, which is a computational framework combining graph-based neural networks with a generative adversarial network (GAN)-inspired training process. By leveraging point cloud data and dynamic graph convolutional neural networks (DGCNNs), GraphCompNet models complex shapes and incorporates position-specific thermal and mechanical factors. A two-stage adversarial training procedure iteratively refines compensated designs via a compensator-predictor architecture, offering real-time feedback and optimization. Experimental validation across diverse shapes and positions shows the framework significantly improves compensation accuracy (35 to 65 percent) across the entire print space, adapting to position-dependent variations. This work advances the development of Digital Twin technology for AM, enabling scalable, real-time monitoring and compensation, and addressing critical gaps in AM process control. The proposed method supports high-precision, automated industrial-scale design and manufacturing systems.

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