Control-Oriented Modeling and Repetitive Control in In-Layer and Cross-Layer Thermal Interactions in Selective Laser Sintering

ASME Letters in Dynamic Systems and Control Pub Date : 2019-10-08 DOI:10.1115/dscc2019-8976

Dan Wang, Tianyu Jiang, Xu Chen

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引用次数: 6

Abstract

Although laser-based additive manufacturing (AM) has enabled unprecedented fabrication of complex parts directly from digital models, broader adoption of the technology remains challenged by insufficient reliability and in-process variations. In pursuit of assuring quality in the selective laser sintering (SLS) AM, this paper builds a modeling and control framework of the key thermodynamic interactions between the laser source and the materials to be processed. First, we develop a three-dimensional finite element simulation to understand the important features of the melt pool evolution for designing sensing and feedback algorithms. We explore how the temperature field is affected by hatch spacing and thermal properties that are temperature-dependent. Based on high-performance computer simulation and experimentation, we then validate the existence and effect of periodic disturbances induced by the repetitive in- and cross-layer thermomechanical interactions. From there, we identify the system model from the laser power to the melt pool width and build a repetitive control algorithm to greatly attenuate variations of the melt pool geometry.

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选择性激光烧结层内和层间热相互作用的面向控制建模和重复控制

尽管基于激光的增材制造(AM)已经能够直接从数字模型制造出前所未有的复杂零件，但该技术的广泛采用仍然受到可靠性不足和工艺变化的挑战。为了保证选择性激光烧结增材制造的质量，本文建立了激光源与被加工材料之间关键热力学相互作用的建模和控制框架。首先，我们开发了一个三维有限元模拟来了解熔池演变的重要特征，以设计传感和反馈算法。我们探讨了温度场如何受到舱口间距和温度相关的热特性的影响。基于高性能计算机模拟和实验，我们验证了重复层内和层间热力学相互作用引起的周期性扰动的存在和影响。在此基础上，我们确定了从激光功率到熔池宽度的系统模型，并建立了一个重复控制算法来极大地衰减熔池几何形状的变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ASME Letters in Dynamic Systems and Control

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