Isaac C Gilfeather, Harold W Pearson-Nadal, Jessica M Andriolo, Jack L Skinner
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引用次数: 0
Abstract
Applications of electrospinning (ES) range from fabrication of biomedical devices and tissue regeneration scaffolds to light manipulation and energy conversion, and even to deposition of materials that act as growth platforms for nanoscale catalysis. One major limitation to wide adoption of ES is stochastic fiber deposition resulting from the chaotic motion of the polymer stream as is approaches the deposition surface. In the past, fabrication of structures or materials with precisely determined mesoscale morphology has been accomplished through modification of electrode shape, use of multi-dimensional electrodes or pins, deposition onto weaving looms, hand-held electrospinning devices that allow the user to guide deposition, or electric field manipulation by lensing elements or apertures. In this work, we demonstrate an ES system that contains multiple high voltage power supplies that are independently controlled through a control algorithm implemented in LabVIEW. The end result is what we term "multiplex ES" where multiple independently controlled high-voltage signals are combined by the ES fiber to result in unique deposition control. COMSOL Multiphysics® software was used to model the electric field produced in this novel ES system. Using the multi-power supply system, we demonstrate fabrication of woven fiber materials that do not require complex deposition surfaces. Time-varied sinusoidal wave inputs were used to create electrospun torus shapes. The outer diameter of the tori was found, through parametric analysis, to be rather insensitive to frequency used during deposition, while inner diameter was inversely related to frequency, resulting in overall width of the tori increasing with frequency. Multiplex ES has a high-frequency cutoff based on the time response of the high voltage electrical circuit. These time constants were measured and minimized through the addition of parallel resistors that decreased impedance of the system and improved the high-frequency cutoff by up to 63%.
电纺丝(ES)的应用范围很广,从制造生物医学设备和组织再生支架,到光操纵和能量转换,甚至到沉积作为纳米级催化生长平台的材料。影响 ES 广泛应用的一个主要限制因素是聚合物流在接近沉积表面时的混乱运动所导致的随机纤维沉积。过去,通过改变电极形状、使用多维电极或插针、在织布机上沉积、允许用户引导沉积的手持式电纺丝设备或通过透镜元件或孔径操纵电场,可以制造出具有精确定位的中尺度形态的结构或材料。在这项工作中,我们展示了一个 ES 系统,该系统包含多个高压电源,可通过 LabVIEW 中实施的控制算法进行独立控制。最终结果就是我们所说的 "多路复用 ES",即 ES 光纤将多个独立控制的高压信号组合在一起,从而实现独特的沉积控制。我们使用 COMSOL Multiphysics® 软件对这种新型 ES 系统中产生的电场进行建模。利用多电源系统,我们演示了无需复杂沉积表面的编织纤维材料的制造。时变正弦波输入用于制造电纺丝环形状。通过参数分析发现,环状体的外径对沉积过程中使用的频率并不敏感,而内径则与频率成反比,导致环状体的整体宽度随频率增加而增加。Multiplex ES 具有基于高压电路时间响应的高频截止。通过测量这些时间常数,并通过增加并联电阻器使其最小化,从而降低了系统阻抗,并将高频截止率提高了 63%。
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