3D打印聚合物孔隙度的微波定量研究

Anna Case, A. McCarville, Mohammad Tayeb Al Qaseer, R. Zoughi
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引用次数: 3

摘要

聚合物的增材制造(或3D打印)是快速成型和生产功能部件的强大技术。然而,这些技术,特别是熔丝制造(FFF)工艺,可能导致零件具有相对较大的孔隙率(即分布的空气空隙)。这种不希望的孔隙度水平可能对打印部件的完整性有害,并最终限制其使用。微波材料表征技术是评估此类孔隙度的绝佳候选,特别是对于聚合物(即介电材料),具有在线过程控制的最终潜力。在这项工作中,众所周知的完全填充波导技术被用于测量几种具有不同控制孔隙率水平的印刷样品的复介电常数。随后,使用两个现有的介电混合模型将介电常数与该参数关联起来以进行量化。
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Microwave Quantification of Porosity Level in 3D Printed Polymers
Additive manufacturing (or 3D printing) of polymers is a powerful technique for rapid prototyping and production of functional parts. However, these techniques, and in particular the fused filament fabrication (FFF) process, can result in parts with relatively large volume of porosity (i.e., distributed air voids). Such undesired levels of porosity can be potentially detrimental to the integrity of a printed part and ultimately limit its use. Microwave material characterization techniques are great candidates for evaluating such porosity, particularly for polymers (i.e., dielectric materials), with the ultimate potential of use for inline process control. In this work the well-known completely-filled waveguide technique is used to measure the complex permittivity of several printed samples with varying controlled porosity levels. Subsequently, two existing dielectric mixing models are used to correlate permittivity to this parameter for quantification purposes.
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