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Higher-order derivatives of rigid body dynamics with application to the dynamic balance of spatial linkages

Jan J. de Jong, Andreas Müller, Just L. Herder

2020Mechanism and Machine Theory21 citationsDOIOpen Access PDF

Abstract

Dynamic balance eliminates the fluctuating reaction forces and moments induced by high-speed robots that would otherwise cause undesired base vibrations, noise and accuracy loss. Many balancing procedures, such as the addition of counter-rotating inertia wheels, increase the complexity and motor torques. There exist, however, a small set of closed-loop linkages that can be balanced by a specific design of the links' mass distribution, potentially leading to simpler and cost-effective solutions. Yet, the intricacy of the balance conditions hinder the extension of this set of linkages. Namely, these conditions contain complex closed-form kinematic models to express them in minimal coordinates. This paper presents an alternative approach by satisfying all higher-order derivatives of the balance conditions, thus avoiding finite closed-form kinematic models while providing a full solution for arbitrary linkages. The resulting dynamic balance conditions are linear in the inertia parameters such that a null space operation, either numeric or symbolic, yield the full design space. The concept of inertia transfer provides a graphical interpretation to retain intuition. A novel dynamically balanced 3-RSR spatially moving mechanism is presented together with known examples to illustrate the method.

Topics & Concepts

KinematicsInertiaControl theory (sociology)Dynamic balanceTorqueComputer scienceMoment of inertiaVibrationMathematicsClassical mechanicsArtificial intelligencePhysicsControl (management)Quantum mechanicsThermodynamicsRobotic Mechanisms and DynamicsDynamics and Control of Mechanical SystemsMechanical Engineering and Vibrations Research
Higher-order derivatives of rigid body dynamics with application to the dynamic balance of spatial linkages | Litcius