Abstract
Long robotic arms are useful for many applications such as nuclear plant decommissioning, inspection, and firefighting. A major problem for designing and operating long robotic arms is that even small end effector reaction forces and arm gravity can result in large loads on proximal arm joints because of long moment arms. To solve that problem, previous researches focus on specifically designed long arms with certain compensation mechanisms. However, those specialized arm designs are difficult to be applied to existing long robotic arms and to be customized for different missions. To overcome those two drawbacks, we recently proposed a watch-like thrust-generating modular device, called flying watch, with the following two major advantages. Firstly, flying watch can be attached to different kinds of existing long robotic arms and generate thrusts to enhance arm strength. And we have proposed a thrust planning method for flying watch in our previous work. Secondly, since different flying watch attachment allocations can enhance the same robotic arm in different ways, flying watch attachment allocations can be customized to meet the needs of a specific mission. However, up to now, customizing flying watch attachment allocations to different missions is still based on human experience and there is no clear performance metric and automated design method for flying watch attachment allocation. To facilitate mission-dependent long arm enhancement, in this paper, we first propose a novel performance metric, called thrust drivability, which measures the ability of a flying watch attachment allocation to counteract unexpected end effector reaction forces. Then based on thrust drivability, we propose an automated design method, called Allocation Optimization based on Weighted Situations (AOWS), for generating mission-dependent flying watch attachment allocations counteracting both unexpected and known external forces. Simulations show that AOWS based allocation designs can counteract both known and unexpected external forces much better than human-experience-based allocation designs.
Highlights
Long-reach robotic arms are very useful for many applications such as nuclear power plant decommissioning [1, 2], inspection [3,4,5], and firefighting [6]
(2) Proposing an automated design method based on thrust drivability, called Allocation Optimization based on Weighted Situations (AOWS), for designing mission-dependent flying watch attachment allocations counteracting both unexpected and known external forces
Overview we propose a novel design method for designing mission-dependent flying watch attachment allocation, called Allocation Optimization based on Weighted Situations (AOWS)
Summary
Long-reach robotic arms are very useful for many applications such as nuclear power plant decommissioning [1, 2], inspection [3,4,5], and firefighting [6]. (2) Proposing an automated design method based on thrust drivability, called Allocation Optimization based on Weighted Situations (AOWS), for designing mission-dependent flying watch attachment allocations counteracting both unexpected and known external forces (including arm gravity). Are respectively the maximum absolute value of normalized joint loads resulting from unexpected end effector reaction forces with zero flying watch thrusts and optimal flying watch thrusts s+u obtained from Problem 2. Increasing ρ(θ , φ) helps reducing the infinity norm of optimal normalized total joint load τ∼∗ ∞ given the same arm configuration, the same unexpected end effector reaction force, and sufficient maximum flying watch thrust. 4. Thrust drivability We hope to derive a quantitative metric from TDS to measure the ability of a flying watch attachment allocation to counteract unexpected end effector reaction forces with different magnitudes and directions. Tor τ ki depends on both flying watch thrust magnitudes and flying watch attachment allocations, the flying watch thrusts must be optimized together with flying watch
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
