A passive walker is dynamic and energy efficient, but is always restricted to a downward gentle slope, and cannot walk on the flat ground. To design and build a bipedal walking robot, as dynamic and energy efficient as a passive walker, and still enable to walk on the flat ground, there is a need for a proper source of energy (actuation) to replace the gravitational energy input. Such an actuation system should allow the robot to walk a larger portion of a gait cycle all by its natural dynamics, and also, the actuation system does not have to suppress the natural dynamics of the robot. Therefore, in this paper, the authors present the design of a passive-based physical bipedal robot which can walk on the flat ground purely based on its natural dynamics (no control and no actuation) for a large portion of a gait cycle with a dynamic and highly energy-efficient gait. The robot has three internal degrees of freedom, i.e., the (active) hip and the two (passive) knees as well as the two round-feet rigidly connected to the two shanks. Only one compliant hip-actuation system is used to allow the robot to perform energy recovery as well as coordination between the energy input and the natural dynamics. The energy is injected at the hip and is stored in a torsional spring at the beginning of each gait cycle (similar or equal to 40% of a gait cycle); such energy is then recovered to enable the robot walking forward entirely by its natural dynamics for the rest of that cycle (similar or equal to 60% of a gait cycle). As a result, the robot can walk with a dynamic and highly energy-efficient gait on the flat ground with a Froude number of 0.176, a mechanical cost of transport of 0.086, and a total cost of transport of 0.236, which are comparable to a human and the best available bipedal walking robots in the literature.

• 出版日期2016-8