Experimental investigation on deformation behavior of TJ-1 lunar soil simulant subjected to principal stress rotation

• Published in: Advances in space research Vol. 52; no. 1; pp. 136 - 146
• Main Authors: Jiang, Mingjing, Li, Liqing, Yang, Qijun
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.07.2013
• Subjects: Deformation behavior; Hollow cylinder apparatus; Non-coaxiality; Principal stress rotation; TJ-1 lunar soil simulant; Deformation behavior; Principal stress rotation; TJ-1 lunar soil simulant; Hollow cylinder apparatus; Non-coaxiality
• ISSN: 0273-1177; 1879-1948
• DOI: 10.1016/j.asr.2013.02.001

The knowledge of mechanical properties of lunar soil is of fundamental importance for the coming exploration of the Moon. This paper aims to investigate the fundamental deformation behavior of lunar soil and the effects of the intermediate principal stress coefficient, deviatoric stress ratio, and mean stress during the principal stress rotation. First, an improved technique was proposed to generate homogeneous samples based on the Multi-layer Undercompaction Method. Second, three series of tests on TJ-1 lunar soil simulant under the principal stress rotation were performed with a hollow cylinder apparatus at Tongji University, China. In each series of tests, only one value of the three variables mentioned above was changed while the others were kept constant. The test results demonstrate that the rotation of principal stress can result in significant plastic deformation, volumetric strain, and non-coaxiality (non-coincidence of the increment direction of principal plastic strain with the principal stress direction) of TJ-1 lunar soil simulant. In addition, it is found that the intermediate principal stress coefficient, deviatoric stress ratio, and mean stress have different influences on the four strain components, i.e. εz,εr,εθ and γzθ, volumetric strain, and non-coaxiality during the principal stress rotation. The influence of deviatoric stress ratio is relatively stronger than the others. Therefore, the influence of principal stress rotation on the deformation behavior of lunar soil should be taken into account carefully in the design and construction of facilities on the lunar surface in the future.