Williams Stuart J, Schneider Joseph D, King Benjamin C, Green Nicolas G
Department of Mechanical Engineering, University of Louisville, Louisville, KY 40292, USA.
Electronics and Computer Science, University of Southampton, Southampton SO17 1BJ, UK.
Micromachines (Basel). 2022 Feb 11;13(2):288. doi: 10.3390/mi13020288.
The electric curtain is a platform developed to lift and transport charged particles in air. Its premise is the manipulation of charged particles; however, fewer investigations isolate dielectric forces that are observed at lower voltages (i.e., less than the Paschen limit). This work focuses on observations of simultaneous dielectrophoretic and electrostatic forces. The electric curtain was a printed circuit board with interdigitated electrodes (0.020 inch width and spacing) coated with a layer of polypropylene, where a standing wave or travelling wave AC signal was applied (50 Hz) to produce an electric field below the Paschen limit. Soda lime glass beads (180-212 µm) demonstrated oscillatory rolling via dielectrophoretic forces. In addition, several particles simultaneously experienced rapid projectile repulsion, a behavior consistent with electrostatic phenomena. This second result is discussed as a particle-induced local increase in the electric field, with simulations demonstrating that a particle in close proximity to the curtain's surface produces a local field enhancement of over 2.5 times. The significance of this is that individual particles themselves can trigger electrostatic repulsion in an otherwise dielectric system. These results could be used for advanced applications where particles themselves provided triggered responses, perhaps for selective sorting of micrometer particles in air.
电幕是一个用于在空气中提升和传输带电粒子而开发的平台。其前提是对带电粒子进行操控;然而,较少有研究分离出在较低电压(即低于帕邢极限)下观察到的介电力。这项工作聚焦于同时对介电泳力和静电力的观测。电幕是一块印刷电路板,带有叉指电极(宽度和间距均为0.020英寸),并涂有一层聚丙烯,在其上施加驻波或行波交流信号(50赫兹)以产生低于帕邢极限的电场。钠钙玻璃珠(180 - 212微米)通过介电泳力表现出振荡滚动。此外,多个粒子同时经历了快速的抛射排斥,这一行为与静电现象一致。这第二个结果被讨论为粒子引起的电场局部增强,模拟表明靠近幕表面的粒子会产生超过2.5倍的局部场增强。其意义在于单个粒子自身能够在原本的介电系统中引发静电排斥。这些结果可用于粒子自身提供触发响应的先进应用中,或许可用于空气中微米级粒子的选择性分选。