In order to realize a long-term lunar exploration, it is essential to develop a technolo-gy for transporting lunar soil for in-situ resource utilization. We are developing a par-ticle transport system that uses electrostatic traveling-waves. The conveyer consists of parallel electrodes printed on a plastic substrate. Four-phase rectangular voltage is applied to the electrodes to transport particles on the conveyer. Ultrasonic vibration was applied to the conveyer to transport particles efficiently. The following points are the outline of our investigation: (1) The observed transport rate in air was 2 g/min. Through numerical calculations based on the 3D distinct element method, we pre-dicted that the system performance would improve in the high vacuum and low-gravity environment on the moon. (2) The power consumption of this system is very less. It was only 4 W for a 1-m~2 area of the conveyer. (3) We demonstrated an inclined and curved transport path as well as a flat and straight transport path. In ad-dition, we demonstrated that transportation of particles through a tube and accumula-tion of scattered particles were also possible.
展开▼
机译:为了实现对月球的长期勘探,必须开发一种运输月球土壤以就地利用资源的技术。我们正在开发使用静电行波的颗粒运输系统。输送机由印刷在塑料基板上的平行电极组成。四相矩形电压施加到电极上,以在输送机上输送颗粒。超声波振动被施加到输送机上以有效地输送颗粒。以下是我们研究的要点:(1)在空气中观察到的传输速率为2 g / min。通过基于3D离散元方法的数值计算,我们预测在月球的高真空和低重力环境下,系统性能将会提高。 (2)该系统的功耗非常小。传送带的1-m〜2区域只有4W。 (3)我们展示了倾斜和弯曲的运输路径以及平坦和笔直的运输路径。此外,我们证明了粒子通过管子的运输和散落粒子的积累也是可能的。
展开▼
