Leg mechanisms for hydraulically actuated robots

The performance of highly dynamic robotic machines is directly associated with both the actuation means and the specific mechanical properties/configuration of the system. Hydraulic actuation demonstrates significant competitive advantages when minimum weight and volume, large forces and wide range of speeds are required and this makes it very suitable for systems such as legged robots. The geometry and design of leg mechanisms have great effect on the actuation system performance such as the required flow, which directly determines the size/weight and power density, in turn affecting the performance of the robot. This paper describes the mechanism and operation principle of two 2-DOF legs considered for HyQ, a hydraulically actuated quadruped robot [1]. Numerical studies have been done to investigate the required flow, the pressure in the actuator chambers and the efficiency of the two leg mechanisms. The results show that the second leg design reduces the required flow significantly with less pressure-jump in the actuator and higher efficiency.

[1]  George T.-C. Chiu,et al.  Adaptive robust motion control of single-rod hydraulic actuators: theory and experiments , 2000 .

[2]  Donaldson McCloy,et al.  Control of fluid power : analysis and design , 1980 .

[3]  Yousheng Yang,et al.  HyQ - Hydraulically actuated quadruped robot: Hopping leg prototype , 2008, 2008 2nd IEEE RAS & EMBS International Conference on Biomedical Robotics and Biomechatronics.

[4]  Kenzo Nonami,et al.  Locomotion Control of a Hydraulically Actuated Hexapod Robot by Robust Adaptive Fuzzy Control with Self-Tuned Adaptation Gain and Dead Zone Fuzzy Pre-compensation , 2008, J. Intell. Robotic Syst..

[5]  Denis J Marcellin-Little,et al.  Reliability of goniometry in Labrador Retrievers. , 2002, American journal of veterinary research.

[6]  Gordon Cheng,et al.  Full-Body Compliant Human–Humanoid Interaction: Balancing in the Presence of Unknown External Forces , 2007, IEEE Transactions on Robotics.

[7]  Masayoshi Tomizuka,et al.  Robust adaptive and repetitive digital tracking control and application to a hydraulic servo for noncircular machining , 1994 .

[8]  Septimiu E. Salcudean,et al.  Nonlinear control of hydraulic robots , 2001, IEEE Trans. Robotics Autom..

[9]  Kevin Blankespoor,et al.  BigDog, the Rough-Terrain Quadruped Robot , 2008 .

[10]  Wen-Hong Zhu,et al.  Adaptive Output Force Tracking Control of Hydraulic Cylinders With Applications to Robot Manipulators , 2005 .

[11]  A. Alleyne,et al.  Nonlinear force/pressure tracking of an electro-hydraulic actuator , 1999 .

[12]  George T.-C. Chiu,et al.  Adaptive robust motion control of single-rod hydraulic actuators: Theory and experiments , 1999, Proceedings of the 1999 American Control Conference (Cat. No. 99CH36251).

[13]  Peter I. Corke,et al.  Model-based control of hydraulically actuated manipulators , 2001, Proceedings 2001 ICRA. IEEE International Conference on Robotics and Automation (Cat. No.01CH37164).

[14]  Rui Liu,et al.  Nonlinear Force/Pressure Tracking of an Electro-Hydraulic Actuator , 2000 .

[15]  H. Kazerooni,et al.  Biomechanical design of the Berkeley lower extremity exoskeleton (BLEEX) , 2006, IEEE/ASME Transactions on Mechatronics.