论文信息 - Development of Grousers with a Tactile Sensor for Wheels of Lunar Exploration Rovers to Measure Sinkage

Development of Grousers with a Tactile Sensor for Wheels of Lunar Exploration Rovers to Measure Sinkage

This paper presents a grouser developed for the wheels of lunar exploration rovers to measure sinkage. The wheels, which are intended to traverse loose soil such as lunar regolith, contain grousers that transfer thrust to the wheels and thus to the body of the rover. The interaction between the wheel (with grousers) and the loose soil can be described using a kinematic model. When traversing loose soil, the wheel sinks into the soil, which necessitates knowledge of the entrance angle needed in order to avoid this problem. If the entrance angle is known, the sinkage can be measured in real time before adverse conditions occur. Because of the importance and usefulness of detecting the entrance angle of the wheel, we herein propose a grouser with an embedded tactile sensor. A strain gauge on the surface of the grousers serves as the tactile sensor. In order to confirm the precision of the proposed grouser, we have performed tests on a rigid surface and loose soil surfaces.

Takashi Kubota | Mitsuhiro Yamano | Kojiro Iizuka | Tatsuya Sasaki

[1] Keiji Nagatani,et al. Experimental study and analysis on driving wheels' performance for planetary exploration rovers moving in deformable soil , 2011 .

[2] Kazuya Yoshida,et al. Terramechanics-based high-fidelity dynamics simulation for wheeled mobile robot on deformable rough terrain , 2010, 2010 IEEE International Conference on Robotics and Automation.

[3] Robert Bauer,et al. A dynamic terramechanic model for small lightweight vehicles with rigid wheels and grousers operating in sandy soil , 2011 .

[4] Matthew Spenko,et al. A modified pressure–sinkage model for small, rigid wheels on deformable terrains , 2011 .

[5] Roland Siegwart,et al. Towards torque control of the CRAB rover , 2008 .

[6] Kazuya Yoshida,et al. Accurate estimation of drawbar pull of wheeled mobile robots traversing sandy terrain using built-in force sensor array wheel , 2009, 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[7] Zongquan Deng,et al. Wheel slip-sinkage and its prediction model of lunar rover , 2010 .

[8] Kazuya Yoshida,et al. Planetary rovers’ wheel–soil interaction mechanics: new challenges and applications for wheeled mobile robots , 2011, Intell. Serv. Robotics.

[9] M. G. Bekker,et al. Theory of land locomotion , 1956 .

[10] Karl Iagnemma,et al. Investigation of Stress and Failure in Granular Soils for Lightweight Robotic Vehicle Applications , 2012 .