Enhanced stiffness modeling of manipulators with passive joints (1104.0769v1)

Abstract: The paper presents a methodology to enhance the stiffness analysis of serial and parallel manipulators with passive joints. It directly takes into account the loading influence on the manipulator configuration and, consequently, on its Jacobians and Hessians. The main contributions of this paper are the introduction of a non-linear stiffness model for the manipulators with passive joints, a relevant numerical technique for its linearization and computing of the Cartesian stiffness matrix which allows rank-deficiency. Within the developed technique, the manipulator elements are presented as pseudo-rigid bodies separated by multidimensional virtual springs and perfect passive joints. Simulation examples are presented that deal with parallel manipulators of the Ortholide family and demonstrate the ability of the developed methodology to describe non-linear behavior of the manipulator structure such as a sudden change of the elastic instability properties (buckling).

• The paper introduces a nonlinear stiffness model that accounts for load-induced nonlinearity in manipulators with passive joints.
• It employs extended virtual joint methods and numerical linearization to compute Cartesian stiffness matrices under various loading conditions.
• The study demonstrates predictive capabilities for elastic instability and buckling, enhancing design reliability in robotic systems.

Enhanced Stiffness Modeling of Manipulators with Passive Joints

The discussed paper introduces a comprehensive methodology designed for improved stiffness analysis of serial and parallel robotic manipulators equipped with passive joints. The authors have systematically accounted for the impact of loading conditions on manipulator configurations, significantly influencing their Jacobians and Hessians. The central contribution of this paper is the proposal of a nonlinear stiffness model applicable to manipulators with passive joints. This model is accompanied by a numerical method for linearization and the computation of the Cartesian stiffness matrix, which accommodates rank deficiency. Key to this research is the modeling of manipulator elements as pseudo-rigid bodies connected by multidimensional virtual springs and perfect passive joints, enabling the capture of manipulator behaviors such as elastic instability and buckling in loaded scenarios.

Core Contributions and Methods

The paper addresses the limitations of traditional stiffness analysis techniques which typically overlook load-induced non-linear behavior in robotic manipulators. Notable existing methods, such as the Finite Element Analysis (FEA), Matrix Structural Analysis (SMA), and Virtual Joint Method (VJM), see enhancements in this paper. The VJM's extension is particularly emphasized, incorporating external and internal loading for more realistic stiffness scenario representations. Conventional approaches usually analyze manipulators in an "unloaded" mode, where external and internal forces are disregarded, simplifying the stiffness analyses to linear relations. This paper extends these techniques to consider "loaded" conditions, thus accommodating nonlinear effects like multiple equilibria and buckling.

The authors introduce an advanced non-linear stiffness analysis heavily dependent on robust computational techniques to detect and analyze the static equilibrium of manipulator configurations under load. Importantly, this approach accounts for virtual joint movements that traditionally are ignored but are crucial under load-inducing configurations.

Key Numerical Techniques and Results

Among the innovative solutions presented, the ability to compute loaded static equilibriums and assess their stability is groundbreaking. This includes identifying possible critical forces that may induce undesired phenomena such as buckling. The stiffness matrix evaluation under loaded conditions reveals non-linear stiffness behaviors, a significant indicator both practically and theoretically. The computational technique offered is noted for its simplicity and reliance on matrices with reduced dimensionality, enabling effective evaluation in complex robotic applications.

For instance, in the illustrative case of the Orthoglide parallel manipulator, the methodology predicts non-linear force-deflection relationships across its workspace, identifying critical points where external forces cause abrupt changes in system stability—highlighting the potential risk of buckling.

Implications and Future Directions

The implications of this research are profound for both robotic system design and application in environments where loaded manipulations are common. It provides robotic designers with a powerful tool to evaluate and counteract potential instabilities, ensuring higher precision and reliability in robotic performance across industrial, medical, and service applications.

Further research will likely extend these methodologies to accommodate even more complex manipulator architectures, including those with cross-linkages and heavier manipulators influenced by distributed loading scenarios—offering a continuation of the advancements in stiffness modeling that this paper highlights. Extensions into more sophisticated parallel architectures could also foster greater rigidity and enhanced functionality for robotic systems in diverse fields.

In summary, this paper significantly advances the state-of-the-art in stiffness modeling by tackling non-linear behaviors in loaded manipulators, enabling designers to foresee and address potential risks inherent in robotic operations under load, thus paving the way for more robust and reliable robotic systems.