Abstract
This paper presents a Thermal Deformation defect prediction method for layered printing using Convolutional Generative Adversarial Network (CGAN). Firstly, the original manifold mesh is converted into layered image in Printing Coordinate System (PCS). The trajectory inside layered image with various infill patterns are generated for making comparisons. Inspired by monocular vision and even binocular vision, the mathematical model of thermal defect prediction via infrared thermogram is built via virtual printing of Digital Twins to preset the initial parameters of Artificial Neural Network (ANN). Particularly, the depth convolution is used to extract multi-scale features of layered image. By using transfer learning techniques to identify small sample data, the CGAN is employed to build the nonlinear implicit relations between thermal deformation and multi-scale features. The binocular stereo vision laser scanner is used to determine the actual thermal deformation of the target printed objects. The shape deformation dissimilarity can be succinctly calculated by evaluating the surface profile error via mesh registration between the original source and target mesh model. The proposed method is verified by physical experiments. The experiment proved that the proposed method can deal with the thermal deformation with more optimal parameters, which contributes to performance forward design of irregular complex parts regarding diversified customized requirements.
Highlights
Additive manufacturing (AM), a representative of superfield manufacturing, enables quick freeform fabrication of complex-geometry components directly from the 3D models [1]
Due to its layer-by-layer additive process, which is the common feature of AM, it can be simpler and quicker to produce complex-geometry components at one time compared with conventional manufacturing process
Aiming at improving geometric precision for 3D printing (3DP) and even 4D printing (4DP), based on the previous representative work [26,27,28,29], the antecedent research background is deepened and continued, the upshot is that this paper proposed a method of deformation-induced defect prediction for layered printing using Convolutional Generative Adversarial Network (CGAN)
Summary
Additive manufacturing (AM), a representative of superfield manufacturing, enables quick freeform fabrication of complex-geometry components directly from the 3D models [1]. Proposed a novel 5-axis dynamic slicing algorithm to achieve non-supporting material printing. Teng et al [18] studied the effects of material property assumptions on predicted meltpool shape for laser powder bed fusion based additive manufacturing. Paul et al developed a three-dimensional thermomechanical finite element (FE) model to [19] calculate the thermal deformation in AM parts based on slice thickness, part orientation, scanning speed, and material properties. Aiming at improving geometric precision for 3D printing (3DP) and even 4DP, based on the previous representative work [26,27,28,29], the antecedent research background is deepened and continued, the upshot is that this paper proposed a method of deformation-induced defect prediction for layered printing using Convolutional Generative Adversarial Network (CGAN).
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