The effect of volume loading on the extrusion of bimodal glass bead mixtures

npj Advanced Manufacturing Pub Date : 2024-09-25 DOI:10.1038/s44334-024-00008-7

Joseph R. Lawrence, Hugh R. Lipic, Timothy D. Manship, Steven F. Son

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Abstract

Additive manufacturing has provided new methods for generating complex geometries of composite energetic materials. Additive manufacturing of ammonium-perchlorate composite propellants through direct-ink-write experiences extrusion limitations due to the high viscosities of highly solids loaded propellants. Vibration-assisted printing (VAP) was developed as a method to extend the extrudability limits and extrusion speeds observed with direct-ink-write systems. This study compares the mass flowrates and extrudability limits for bimodal mixtures of glass beads and hydroxyl-terminated polybutadiene (HTPB) binder for both VAP and direct-ink-write printing as a function of volume percent solids loading. The VAP system was able to print higher volume loadings and significantly higher mass flowrate than the direct-ink-write system. The bimodal glass bead mixtures were also compared to a previous study that focused on the extrusion of monomodal glass beads/HTPB mixtures. Interestingly, bimodal mixtures were shown to extrude quicker than monomodal mixtures at all volume loadings and across both printing systems.

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体积负载对双峰玻璃珠混合物挤压的影响

增材制造为生成复杂几何形状的复合高能材料提供了新方法。由于高固体负荷推进剂的粘度较高，通过直接墨水写入法进行的高氯酸铵复合推进剂快速成型制造受到挤压限制。振动辅助打印（VAP）作为一种方法被开发出来，以扩展直接墨水写入系统的挤出限制和挤出速度。本研究比较了玻璃珠和羟基封端聚丁二烯（HTPB）粘合剂的双峰混合物在 VAP 和直接墨水写入印刷中的质量流速和挤出性极限与固体体积百分比的函数关系。与直接墨水写入系统相比，VAP 系统能够打印更高的体积负荷和更高的质量流量。双模玻璃微珠混合物还与之前一项关于单模玻璃微珠/HTPB 混合物挤压的研究进行了比较。有趣的是，在所有体积负载和两种印刷系统中，双模混合物的挤出速度都快于单模混合物。

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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npj Advanced Manufacturing

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