类液体固体中高速3D打印的稳定性

Stability of High Speed 3D Printing in Liquid-Like Solids.

作者信息

LeBlanc Kyle J, Niemi Sean R, Bennett Alexander I, Harris Kathryn L, Schulze Kyle D, Sawyer W Gregory, Taylor Curtis, Angelini Thomas E

机构信息

Department of Mechanical and Aerospace Engineering, University of Florida, Gainesville, Florida 32611, United States.

Department of Materials Science and Engineering, University of Florida, Gainesville, Florida 32611, United States.

出版信息

ACS Biomater Sci Eng. 2016 Oct 10;2(10):1796-1799. doi: 10.1021/acsbiomaterials.6b00184. Epub 2016 Aug 31.

DOI:10.1021/acsbiomaterials.6b00184

PMID:33440477

Abstract

Fluid instabilities limit the ability of features to hold their shape in many types of 3D printing as liquid inks solidify into written structures. By 3D printing directly into a continuum of jammed granular microgels, these instabilities are circumvented by eliminating surface tension and body forces. However, this type of 3D printing process is potentially limited by inertial instabilities if performed at high speeds where turbulence may destroy features as they are written. Here, we design and test a high-speed 3D printing experimental system to identify the instabilities that arise when an injection nozzle translates at 1 m/s. We find that the viscosity of the injected material can control the Reynold's instability, and we discover an additional, unanticipated instability near the top surface of the granular microgel medium.

摘要

在许多类型的3D打印中，当液体墨水固化成书写结构时，流体不稳定性会限制特征保持其形状的能力。通过直接在连续的堵塞颗粒微凝胶中进行3D打印，消除表面张力和体力可以规避这些不稳定性。然而，如果在高速下进行这种3D打印过程，由于湍流可能会在特征书写时将其破坏，因此可能会受到惯性不稳定性的限制。在这里，我们设计并测试了一个高速3D打印实验系统，以识别当注射喷嘴以1米/秒的速度平移时出现的不稳定性。我们发现注入材料的粘度可以控制雷诺不稳定性，并且我们在颗粒微凝胶介质的顶面附近发现了另一种意外的不稳定性。

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类液体固体中高速3D打印的稳定性

Stability of High Speed 3D Printing in Liquid-Like Solids.

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