Wheel slip-sinkage and its prediction model of lunar rover

Liang Ding; Hai-bo Gao; Zong-quan Deng; Jian-guo Tao

doi:10.1007/s11771-010-0021-7

Journal of Central South University ›› 2010, Vol. 17 ›› Issue (1) : 129 -135. DOI: 10.1007/s11771-010-0021-7

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Wheel slip-sinkage and its prediction model of lunar rover

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Abstract

In order to investigate wheel slip-sinkage problem, which is important for the design, control and simulation of lunar rovers, experiments were carried out with a wheel-soil interaction test system to measure the sinkage of three types of wheels in dimension with wheel lugs of different heights and numbers under a series of slip ratios (0–0.6). The curves of wheel sinkage versus slip ratio were obtained and it was found that the sinkage with slip ratio of 0.6 is 3–7 times of the static sinkage. Based on the experimental results, the slip-sinkage principle of lunar’s rover lugged wheels (including the sinkage caused by longitudinal flow and side flow of soil, and soil digging of wheel lugs) was analyzed, and corresponding calculation equations were derived. All the factors that can cause slip sinkage were considered to improve the conventional wheel-soil interaction model, and a formula of changing the sinkage exponent with the slip ratio was established. Mathematical model for calculating the sinkage of wheel according to vertical load and slip ratio was developed. Calculation results show that this model can predict the slip-sinkage of wheel with high precision, making up the deficiency of Wong-Reece model that mainly reflects longitudinal slip-sinkage.

Keywords

lunar rover / slip-sinkage / loose lunar soil / stress distribution / slip ratio

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Liang Ding, Hai-bo Gao, Zong-quan Deng, Jian-guo Tao. Wheel slip-sinkage and its prediction model of lunar rover. Journal of Central South University, 2010, 17(1): 129-135 DOI:10.1007/s11771-010-0021-7

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