Authors: Voss Harrigan, Korey Carter, Mohammad Reza Shaeri

Abstract:

Detrimental effects of lunar dust on space hardware, spacesuits, and astronauts’ health have been already identified during Apollo missions. Developing effective dust mitigation technologies is critically important for successful space exploration and related missions in NASA applications. In this study, an electrostatic cleaning system (ECS) integrated with a negatively ionized Thunderon brush was developed to mitigate small-sized lunar dust particles with diameters ranging from 0.04 µm to 35 µm, and the mean and median size of 7 µm and 5 µm, respectively. It was found that the frequency pulses of the negative ion generator caused particles to stick to the Thunderon bristles and repel between the pulses. The brush was used manually to ensure that particles were removed from areas where the ECS failed to mitigate the lunar simulant. The acquired data demonstrated that the developed system removed over 91-96% of the lunar dust particles. The present study was performed as a proof-of-concept to enhance the cleaning performance of ECSs by integrating a brushing process. Suggestions were made to further improve the performance of the developed technology through future research.

Keywords: lunar dust mitigation, electrostatic cleaning system, brushing, Thunderon brush, cleaning rate

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References:

[1] B. Farr, X. Wang, J. Goree, I. Hahn, U. Israelsson, M. Horanyi, “Dust mitigation technology for lunar exploration utilizing an electron beam,” Acta Astronaut. vol. 177, pp. 405–409, 2020.
[2] C. I. Calle, C. R. Buhler, M. R. Johansen, M. D. Hogue, S. J. Snyder, “Active dust control and mitigation technology for lunar and Martian exploration,” Acta Astronaut., vol. 69, pp. 1082 –1088, 2011.
[3] R. Christoffersen, J. F. Lindsay, S. K. Noble, M. A. Meador, J. J. Kosmo, J. A. Lawrence, L. Brostoff, A. Young, T. McCue, “Lunar dust effects on spacesuit systems insights from the Apollo spacesuits,” Johnson Space Center, 2009.
[4] N. Afshar-Mohajer, C-Y. Wu, J. S. Curtis, J. R. Gaier, “Review of dust transport and mitigation technologies in lunar and Martian atmospheres,” Adv. Space Res. vol. 56, pp. 1222–1241, 2015.
[5] Z. Mao, G. R. Liu, “A smoothed particle hydrodynamics model for electrostatic transport of charged lunar dust on the moon surface,” Comput. Part. Mech. vol. 5, pp. 539–551, 2018.
[6] J. Jiang, Y. Lu, X. Yan, L. Wang, “An optimization dust-removing electrode design method aiming at improving dust mitigation efficiency in lunar exploration,” Acta Astronaut. vol. 166, pp. 59–68, 2020.
[7] K. K. Manyapu, L. Peltz, P. D. Leon, “Extending the utilization of dust protection systems using carbon nanotube embedded materials for lunar habitats for exploration missions,” J. Space Saf. Eng. vol. 6, pp. 248–255, 2019.
[8] H. Kawamoto, S. Hashime, “Practical performance of an electrostatic cleaning system for removal of lunar dust from optical elements utilizing electrostatic traveling wave,” J. Electrostat. vol. 94, pp. 38–43, 2018.
[9] H. Tang, X. Li, S. Zhang, S. Wang, J. Liu, S. Li, Y. Li, Y. Wu, “A lunar dust simulant: CLDS-i,” Adv. Space Res. vol. 59, pp. 1156–1160, 2017.
[10] M. Gondhalekar, C. Parks, N. Shetty, B. Wang, “Mitigation and prevention of lunar dust on NASA Artemis xEMU spacesuits,” 2020.
[11] N. Afshar-Mohajer, C-Y. Wu, R. Moore, N. Sorloaica-Hickman, “Design of an electrostatic lunar dust repeller for mitigating dust deposition and evaluation of its removal efficiency,” J. Aerosol Sci., vol. 69, pp. 21–31, 2014.
[12] 2020 NASA Technology Taxonomy (https://www.nasa.gov), 2020.
[13] J. R. Gaier, K. Journey, S. Christopher, S. Davis, “Evaluation of brushing as a lunar dust mitigation strategy for thermal control surfaces,” In International Conference on Environmental Systems, July 2011, Portland, Oregon.
[14] H. Kawamoto, “Electrostatic and magnetic cleaning systems for removing lunar dust adhering to spacesuits,” In Earth and Space 2012: Engineering, Science, Construction, and Operations in Challenging Environments, pp. 94–103, 2012.
[15] S. A. M. Said, G. Hassan, H. M. Walwil, N. Al-Aqeeli, “The effect of environmental factors and dust accumulation on photovoltaic modules and dust-accumulation mitigation strategies,” Renewable Sustainable Energy Rev. vol. 82, pp. 743–760, 2018.
[16] H. Kawamoto, “Improved electrostatic shield for lunar dust entering into mechanical seals of equipment used for long-term lunar exploration,” 44th International Conference on Environmental Systems, July 2014, Tucson, Arizona.
[17] H. Kawamoto, N. Hara, “Electrostatic cleaning system for removing lunar dust adhering to space suits” J. Aerosp. Eng. vol. 24, pp. 442–444, 2011.
[18] H. Kawamoto, M. Uchiyama, B. L. Cooper, D. S. McKay, “Mitigation of lunar dust on solar panels and optical elements utilizing electrostatic traveling-wave,” J. Electrostat. vol. 69, pp. 370–379, 2011.
[19] D. Cadogan, J. Ferl, “Dust mitigation solutions for lunar and Mars surface systems,” No. 2007-01-3213. SAE Technical Paper, 2007