Simulation and Analysis of the Lunar Regolith Sampling Process Based on the Discrete Element Method

Liu, Tianxi; Cheng, Wei; Liang, Lihua; Zhang, Jiang; Zhao, Yizhi

doi:10.2322/tjsass.57.309

Cited by 12 publications

(1 citation statement)

References 12 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Considering the low gravity on the surface of the Moon (1.62 m/s 2 ), lunar dust formation and migration plays an even bigger role, as there are large numbers of fine particles and they settle only slowly. Furthermore, lunar dust is known to become highly electrostatically charged, sticking to surfaces and thus, damaging equipment [ 97 ] and affecting lunar rover movement [ 28 , 98 , 99 , 100 ].…”

Section: Properties Of Lunar Regolith Simulantsmentioning

confidence: 99%

Geotechnical and Shear Behavior of Novel Lunar Regolith Simulants TUBS-M, TUBS-T, and TUBS-I

et al. 2022

View full text Add to dashboard Cite

The return to the Moon is an important short-term goal of NASA and other international space agencies. To minimize mission risks, technologies, such as rovers or regolith processing systems, must be developed and tested on Earth using lunar regolith simulants that closely resemble the properties of real lunar soil. So far, no singular lunar simulant can cover the multitude of use cases that lunar regolith involves, and most available materials are poorly characterized. To overcome this major gap, a unique modular system for flexible adaptable novel lunar regolith simulants was developed and chemically characterized in earlier works. To supplement this, the present study provides comprehensive investigations regarding geotechnical properties of the three base regolith simulant systems: TUBS-M, TUBS-T, and TUBS-I. To evaluate the engineering and flow properties of these heterogeneous materials under various conditions, shear tests, particle size analyses, scanning electron microscope observations, and density investigations were conducted. It was shown that small grains <25 µm (lunar dust) are highly compressive and cohesive even at low external stress. They are particularly important as a large amount of fine dust is present in lunar regolith and simulants (x50 = 76.7 to 96.0 µm). Further, ring shear and densification tests revealed correlations with damage mechanisms caused by local stress peaks for grains in the mm range. In addition, an explanation for the occurrence of considerable differences in the literature-based data for particle sizes was established by comparing various measurement procedures. The present study shows detailed geotechnical investigations of novel lunar regolith simulants, which can be used for the development of equipment for future lunar exploration missions and in situ resource utilization under realistic conditions. The results also provide evidence about possible correlations and causes of known soil-induced mission risks that so far have mostly been described phenomenologically.

show abstract

Section: Properties Of Lunar Regolith Simulantsmentioning

confidence: 99%

Geotechnical and Shear Behavior of Novel Lunar Regolith Simulants TUBS-M, TUBS-T, and TUBS-I

et al. 2022

View full text Add to dashboard Cite

show abstract

Excavation and Conveying Technologies for Space Applications

Höber

Taschner

Fimbinger

2021

Berg Huettenmaenn Monatsh

View full text Add to dashboard Cite

A rising number of companies and organisations are researching space technologies supporting extraterrestrial life. Whether Moon or Mars, the number of rocket launches is increasing year by year. The majority of National Space Agencies are planning exploration missions with fully autonomous robots, which can conduct several studies about the composition of the lunar dust. Especially the extraction of oxygen from the moon dust, called regolith, is of great interest. Also many other projects are planned. But the initial step of all processes is often forgotten: it is the supply of raw materials. Therefore, a closer look at the possibilities of excavating and conveying regolith has been taken. The research ranges from concept development, calculation to simulation and designing a robotic system.

show abstract

Analysis of the stability of micro-tunnels in lunar regolith with the Discrete Element Method

et al. 2022

View full text Add to dashboard Cite

Simulation and Analysis of the Lunar Regolith Sampling Process Based on the Discrete Element Method

Cited by 12 publications

References 12 publications

Geotechnical and Shear Behavior of Novel Lunar Regolith Simulants TUBS-M, TUBS-T, and TUBS-I

Geotechnical and Shear Behavior of Novel Lunar Regolith Simulants TUBS-M, TUBS-T, and TUBS-I

Excavation and Conveying Technologies for Space Applications

Analysis of the stability of micro-tunnels in lunar regolith with the Discrete Element Method

Contact Info

Product

Resources

About