Kai Xu scite author profile

Geometric fidelity of 3D printed products is critical for additive manufacturing (AM) to be a direct manufacturing technology. Shape deviations of AM built products can be attributed to multiple variation sources such as substrate geometry defect, disturbance in process variables, and material phase change. Three strategies have been reported to improve geometric quality in AM: (1) control process variables x based on the observed disturbance of process variables Ax, (2) control process variables x based on the observed product deviation Ay, and (3) control input product geometry y based on the observed product deviation Ay. This study adopts the third strategy which changes the computer-aided design (CAD) design by optimally compensating the product deviations. To accomplish the goal, a predictive model is desirable to forecast the quality of a wide class o f product shapes, particularly considering the vast library of AM built products with complex geometry. Built upon our previous optimal compensation study of cylindrical products, this work aims at a novel statistical predictive modeling and compensation approach to predict and improve the quality of both cylindrical and prismatic parts. Ex perimental investigation and validation of polyhedrons a indicates the promise of predict ing and compensating a wide class of products built through 3D printing technology.

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Predictive modeling of geometric deviations of 3D printed products - A unified modeling approach for cylindrical and polygon shapes

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Kai Xu

Statistical Predictive Modeling and Compensation of Geometric Deviations of Three-Dimensional Printed Products

Predictive modeling of geometric deviations of 3D printed products - A unified modeling approach for cylindrical and polygon shapes

Fatigue analysis of the gearbox housing in high-speed trains under wheel polygonization using a multibody dynamics algorithm

New protein-resistant surfaces of amphiphilic graft copolymers containing hydrophilic poly(ethylene glycol) and low surface energy fluorosiloxane side-chains

A novel design method of the impact zone of a high-speed train

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